Frame-rate based illumination control at display device

ABSTRACT

A display system includes a rendering device and a display device. The rendering device is to render a sequence of frames for display at a frame rate and to set an illumination configuration to be applied by the display device during a frame period for each frame of the sequence of frames based on the frame rate. The illumination configuration controls at least one of an illumination level and a duration for an illumination strobe, and at least one of an illumination level for an illumination fill preceding the illumination strobe in the frame period and an illumination level for an illumination fill following the illumination strobe in the frame period. The display device is to receive a representation of the illumination configuration from the rendering device and apply the illumination configuration during a frame period for each frame of the sequence of frames to display the frame.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a Continuation application of U.S. patentapplication Ser. No. 16/670,618, entitled “FRAME-RATE BASED ILLUMINATIONCONTROL AT DISPLAY DEVICE,” filed on Oct. 31, 2019, claiming priority toU.S. Provisional Application No. 62/788,536, entitled “VARIABLE STROBELIGHT AMOUNT BASED ON FRAME RATE OF FOVEAL AREA,” filed on Jan. 4, 2019,and claiming priority to U.S. Provisional Application No. 62/853,032,entitled “ILLUMINATION CONTROL AT DISPLAY DEVICE,” filed on May 26,2019, the entirety of which is incorporated by reference herein.

The present application is related to the following co-pending patentapplications, the entirety of which are incorporated by referenceherein:

U.S. patent application Ser. No. 16/670,635, entitled “STROBECONFIGURATION FOR ILLUMINATION OF FRAME AT DISPLAY DEVICE” and filed oneven date herewith;

U.S. patent application Ser. No. 16/670,673, entitled “REGION-BY-REGIONILLUMINATION CONTROL AT DISPLAY DEVICE BASED ON PER-REGION BRIGHTNESS”and filed on even date herewith;

U.S. patent application Ser. No. 16/670,651, entitled “REGION-BY-REGIONILLUMINATION CONTROL AT DISPLAY DEVICE BASED ON PER-REGION MOTIONESTIMATION” and filed on even date herewith; and

U.S. patent application Ser. No. 16/670,664, entitled “FOVEATEDILLUMINATION CONTROL AT DISPLAY DEVICE” and filed on even date herewith.

BACKGROUND

Liquid crystal displays (LCDs), light emitting diode (LED) displays,organic LED (OLED) displays, and other emissive, transmissive, andreflective displays conventionally implement one of two illuminationconfigurations: a constant illumination configuration in which thebacklight or emissive pixel elements are constantly active at a fixedlevel for the duration of each frame period; and a strobe configurationin which the backlight or emissive pixel elements are strobed (or“flashed”) for only a brief portion of each frame period and otherwisedeactivated in the periods proceeding and following the strobe. Displaysimplementing a constant illumination configuration typically exhibitlittle if any flicker as the illumination level is constant across eachframe period and between each frame period. However, any movement ofobjects in the displayed content between frames is susceptible to motionblur due to the persistence of vision phenomenon exhibited by the humanvisual system. Conversely, displays implementing a strobe configurationtypically exhibit substantially reduced motion blur due to the briefillumination period during each frame period, but the strobing of thebacklight or emissive pixel elements introduces flicker that has thepotential to detract from a user's experience. Moreover, the currentflows required to provide a sufficiently bright strobe so as to maintaina sufficient average brightness over a series of frame periods typicallyresults in shortened lifespans for the backlight drivers providing suchcurrent flows or the emissive pixel elements providing the flashedlight.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure is better understood, and its numerous featuresand advantages made apparent to those skilled in the art by referencingthe accompanying drawings. The use of the same reference symbols indifferent drawings indicates similar or identical items.

FIG. 1 is a diagram illustrating illumination control during display offrames at a display device in accordance with some embodiments.

FIG. 2 is a diagram illustrating various illumination control techniquesand their combinations in accordance with some embodiments.

FIG. 3 is a block diagram illustrating a display system employing one ormore illumination control techniques in accordance with someembodiments.

FIG. 4 is a block diagram illustrating an example transmissive-typedisplay device in accordance with some embodiments.

FIG. 5 is a block diagram illustrating an example emissive-type displaydevice in accordance with some embodiments.

FIG. 6 is a block diagram illustrating various example display deviceconfigurations for regional illumination control in accordance with someembodiments.

FIG. 7 is a block diagram illustrating a software/hardware stackimplemented by the display system of FIG. 3 in accordance with someembodiments.

FIG. 8 is a flow diagram illustrating a method for frame rate-basedillumination control of a display device in accordance with someembodiments.

FIG. 9 is a diagram illustrating a technique for determining strobe andfill illumination outputs based on frame rate in accordance with someembodiments.

FIG. 10 is a diagram illustrating example relationships between strobeand after-strobe fill illumination outputs based on frame rate inaccordance with some embodiments.

FIG. 11 is a diagram illustrating example illumination configurationsfor a display device at different frame rates based on the relationshipof FIG. 10 in accordance with some embodiments.

FIG. 12 is a diagram illustrating an example relationship betweenstrobe, before-strobe fill, and after-strobe illumination outputs basedon frame rate in accordance with some embodiments.

FIG. 13 is a diagram illustrating example illumination configurationsfor a display device at different frame rates based on the relationshipof FIG. 12 in accordance with some embodiments.

FIG. 14 is a diagram illustrating example illumination strobe timings inaccordance with some embodiments.

FIG. 15 is a diagram illustrating a technique for illumination strobetiming in accordance with some embodiments.

FIG. 16 is a diagram illustrating a graphical user interface tofacilitate receipt of user input on various illumination controlparameters in accordance with some embodiments.

FIG. 17 is a diagram illustrating a technique for crowd-sourcedillumination control in accordance with some embodiments.

FIG. 18 is a flow diagram illustrating a method for per-regionillumination control based on regional brightness in accordance withsome embodiments.

FIG. 19 is a diagram illustrating an example implementation for themethod of FIG. 18 in accordance with some embodiments.

FIG. 20 is a flow diagram illustrating a method for per-regionillumination control based on regional motion estimations in accordancewith some embodiments.

FIG. 21 is a diagram illustrating an example implementation for themethod of FIG. 20 in accordance with some embodiments.

FIG. 22 is a diagram illustrating an example application of the methodof FIG. 20 to two successive frames in accordance with some embodiments.

FIG. 23 is a diagram illustrating a gaze tracking subsystem for thedisplay system of FIG. 3 in accordance with some embodiments.

FIG. 24 is a flow diagram illustrating a method for foveatedillumination control in accordance with some embodiments.

FIG. 25 is a diagram illustrating an example implementation for themethod of FIG. 24 in accordance with some embodiments.

FIG. 26 is a diagram illustrating an example application of the methodof FIG. 24 to two successive frames in accordance with some embodiments.

DETAILED DESCRIPTION

In the following description, numerous specific details are set forth toprovide a thorough understanding of the systems and techniques presentedherein. However, one having ordinary skill in the art should recognizethat the various embodiments can be practiced without these specificdetails. In some instances, well-known structures, components, signals,computer program instructions, and techniques have not been shown indetail to avoid obscuring the approaches described herein. Moreover, itwill be appreciated that for simplicity and clarity of illustration,elements shown in the figures have not necessarily been drawn to scale.For example, the dimensions of some of the elements could be exaggeratedrelative to other elements.

Display devices present video, graphics, and other imagery to a userthrough the display of sequences of display frames (hereinafter, simply“frames”), with the display of each frame of a sequence being associatedwith a corresponding frame period, which is the inverse of the framerate of the corresponding sequence. Each frame is rendered or otherwisegenerated and the pixel data representing the frame is buffered in aframe buffer or other storage component. As illustrated by timing chart100 of FIG. 1, at the start of a frame period 102-1 (signaled by, forexample, assertion of a vertical sync (VSYNC) 104-1 or a verticalblanking interval (VBI)), the pixel data for the frame to be displayedduring the frame period is scanned out of the frame buffer on arow-by-row basis and transmitted to the display device (as representedby scan out line 106), whereupon the display device configures acorresponding row of a pixel matrix composed of, for example, a matrixof liquid crystals (LCs), light emitting diodes (LEDs) or organic LEDs(OLEDs), based on the pixel data of the row of the frame currently beingscanned in. The display device causes the “display” of the frame throughthe emission of display light that is modulated at each pixel inaccordance with the pixel data associated with that pixel's location.For liquid crystal displays (LCDs) and other transmissive-type displaydevices, the emission of display light is achieved through the use of awhite backlight and through configuration of each LC at a pixel locationbased on the pixel data for that pixel location so as to modulate thefrequency and intensity of the backlight passing through the LC so thatthe resulting transmitted light has a corresponding color and intensity.Reflective-type displays operate in a similar manner, but usingreflected light rather than backlighting. For LED displays, OLEDdisplays, and other emissive-type display devices, the emission ofdisplay light is achieved through activation of the LED or OLEDsubpixels of different colors (e.g., red, green, and blue) at differentintensities so that the combined light emitted by the subpixels combinesto provide a particular color and intensity corresponding to the pixeldata associated with that pixel.

Whether through emissive, transmissive, or reflection of light, theportion of the frame period during which display light is beinggenerated by the display device so as to display a corresponding frameto a user is referred to herein as the “illumination” of the frame. Someconventional display systems employ a constant illumination approach inwhich the illumination intensity is maintained at a constant level forthe entire duration of the frame period. To illustrate, timing chart 110of FIG. 1 illustrates a conventional constant illumination technique inwhich a display device controls the illumination source(s) (e.g., thebacklight for an LCD display or the pixels themselves for an LED or LEDdisplay) so that the light output 112 is maintained at a constant levelL across the entire frame period for each frame period 102-1, 102-2, andso on. This approach typically eliminates display flicker as theillumination level is constant within the frame period and between frameperiods, but can instill motion blur for display content in motionbetween successive frames due to the persistence of vision phenomenon.

Accordingly, to mitigate motion blur, some conventional display systemsemploy an opposite approach in which illumination occurs for only abrief portion of the frame period, with this brief illumination referredto as an illumination “strobe” (or “flash”). To illustrate, timing chart120 illustrates a conventional strobed illumination technique in which adisplay device controls the illumination source(s) so that the lightoutput 122 of the illumination sources is non-zero for only arelatively-small portion of each frame period 102 (that is, no greaterthan 25%, 20%, 15%, or even 10% of the frame period), and thuseffectively forming an illumination strobe 124 that is activated brieflyduring the frame period 102 (e.g., 0.5 to 2 milliseconds). While thisresults in the frame being “displayed” as emitted display light for onlya relatively short period of time and thus substantially avoiding imagepersistence and therefore mitigating motion blur, the illuminationstrobe 124 occurring during each frame period 102 introduces alow-frequency flashing that can be perceived by some users as displayflicker. Moreover, to provide an adequate average brightness level, theintensity level of the illumination strobe 124 generally must be setsubstantially higher than the intensity level needed for the constantillumination approach, and thus results in substantial current outflowby the drivers of the illumination source(s) during the illuminationstrobe 124. This increased current outflow typically results in adecreased lifespan for the illumination source or requiresimplementation of heavier-duty driver circuitry, which often is costprohibitive. Moreover, the timing of the strobe 124 itself can impactthe display of the frame, with a strobe occurring earlier in the frameperiod providing reduced latency but increased potential for ghosting,while a later-occurring strobe can reduce or eliminate ghosting but atthe cost of increased latency.

To better balance jitter, motion blur, and latency, the presentapplication discloses various techniques for control of the illuminationconfiguration employed by a display device for illuminating a displayframe based on one or more parameters, including frame rate, userpreferences, original equipment manufacturer (OEM) settings, hardwareperformance capabilities, current hardware state, image content, usergaze direction, and the like. Referring now to FIG. 2, a taxonomy 200 ofthese various illumination control techniques, and various combinationsthereof, are illustrated with reference to timing chart 130 of FIG. 1.The illumination control techniques described herein can be generallycategorized as: techniques for configuring the illumination level(s) anddurations implemented within a frame period based on frame rate(hereinafter referred to as “frame rate-based illumination controltechniques 202; techniques for configuration the position of anillumination strobe within a frame period (hereinafter referred to as“strobe position control techniques 204”); and techniques forcontrolling the illumination configuration on a region-by-region basis(hereinafter referred to as “regional illumination control techniques206”).

In at least one embodiment, the backlighting level (fortransmissive-type display devices) or the baseline illumination level(for emissive-type display devices) is varied over each frame periodduring the display of a sequence of frames in accordance with the“illumination configuration” for that frame period. As illustrated bytiming chart 130 of FIG. 1, the illumination configuration for a frameperiod includes, for example, the selective implementation of anillumination strobe 134, selective implementation of a constantillumination level preceding the illumination strobe 134 (referred toherein as “front illumination fill” or simply “front fill”), andselective implementation of a constant illumination level following theillumination strobe 134 (referred to herein as “back illumination fill”or simply “back fill”), or a combination thereof. A front illuminationfill 138 “fills” the portion of the frame period 102 preceding theillumination strobe 134 (that is, extends from the start of the frameperiod 102 to the start of the illumination strobe 134). A backillumination fill 140 “fills” the portion of the frame period followingthe illumination strobe 134 (that is, extends from the end of theillumination strobe 134 to the end of the frame period 102).Accordingly, in such instances, a frame rate-based illumination controltechnique 202 is employed to control whether the illumination strobe 134is implemented for a given frame period, as well as the “output” of oneor more of an implemented illumination strobe 134, the frontillumination fill 138, and the back illumination fill 140, based atleast on the frame rate of the sequence of frames being displayed. Asused herein, the “output” of an illumination strobe or illumination fillrefers to the product of the illumination level and duration of thecorresponding strobe or fill. Such techniques include, but are notlimited to, a technique 208 for adjusting the illumination level orduration of strobe 134 relative to one or both of the front illuminationfill 138 or the back illumination fill 140 based on frame rate, and atechnique 210 for adjusting the front illumination fill 138 and the backillumination fill 140 relative to each other based on frame rate. Thesetechniques are described in greater detail below with reference to FIGS.9-13.

In the event that an illumination strobe is to be implemented as part ofthe illumination configuration for a frame period, the position of theillumination strobe (e.g., position 136 of illumination strobe 134 oftiming chart 130, FIG. 1) within the corresponding frame period canaffect the display of a frame and the user's perception of the displayedframe. Accordingly, one or more strobe position control technique 204can be implemented to more effectively position an illumination strobewithin a frame period based on any of a variety of factors, such asframe rate, user preference, presence of a delayed VSYNC or next framestart, and the like. The strobe position control techniques 204 aredescribed in greater detail below with reference to FIGS. 14 and 15.

Further, in some embodiments the display device employs backlighting ora display matrix that has individually-controllable illuminationregions, that is, can be controlled on a region-by-region basis. In suchinstances, a regional illumination control technique 206 can be employedto control the illumination configuration for each illumination regionbased on a variety of considerations. For example, a technique 212 forregional illumination control employs per-region brightness measurementsor other brightness representations for a frame to be displayed to set astrobe-based illumination configuration for one or more illuminationregions for the frame period corresponding to the frame. As anotherexample, a technique 214 for regional illumination control employsmotion estimation or other motion analysis to evaluate the motion ofobjects within each region of a frame associated with a correspondingillumination region of the display device and to set the illuminationconfiguration for each illumination region when the frame is displayed.As yet another example, a technique 216 relies on a gaze trackingsubsystem to identify a gaze location on the display matrix to identifywhich illumination region is a foveal region and which illuminationregions are peripheral regions, and then setting the illuminationconfiguration for each illumination region during display of a frameaccordingly. Note that reference to “region”, “regional”, or“regionally”, as used herein, in addition to referring to multipleregions, can also refer to a single global region for the entire displaydevice, unless otherwise noted. Moreover, the per-region analysisdescribed herein may be used to control the illumination of a differentnumber of regions—that is, the number of regions analyzed may be greaterthan, less than, or equal to the number of regions having illuminationcontrol as a result of such analysis. These regional illuminationcontrol techniques 206 are described in greater detail below withreference to FIGS. 18-26.

The techniques for illumination control described herein typicallyconsider one or more factors, such as frame rate, in determining acorresponding illumination configuration for one or more frame periods.In some embodiments, the relationship between the input factors and theresulting parameters for the illumination configuration is a fixedrelationship 218, implemented as, for example, one or more look-uptables (LUTs), as a functional representation or algorithmicrepresentation, and the like. In other embodiments, the relationshipbetween the input factors and the resulting parameters for theillumination configuration is an adaptive relationship 220 that employsmachine learning to dynamically adjust the relationship based on amodeling of the behavior of the display system. In still otherembodiments, the relationship is a combination of a fixed relationship218 and an adaptive relationship 220. Whether fixed, adaptive, or acombination thereof, the relationship between input factors and outputparameters for an illumination configuration for one or more frameperiods can be set based on original equipment manufacturer (OEM) inputor control 222, based on user input or control 224, set based on inputor control from other users of similar systems, or a combinationthereof, as described in greater detail below with reference to FIGS. 16and 17.

As represented by lines 228, 230, and 232, control of the illuminationconfiguration for a frame period is not limited to employment of onlyone technique or only techniques of the same type. To illustrate, insome embodiments one or more frame rate-based illumination controltechniques 202 are employed individually or in combination with one ormore regional illumination control techniques 206, in combination withone or more strobe position control techniques 204, or in combinationwith both one or more regional illumination control techniques 206 andone or more strobe position control techniques 204. Similarly, in someembodiments one or more strobe position control techniques 204 areemployed individually or in combination with one or more regionalillumination control techniques 206, or one or more regionalillumination control techniques 206 are employed together.

Note that for ease of illustration, some of the illumination controltechniques are described herein as involving the determination of anillumination configuration based on one or more aspects of a frame to bedisplayed and then implementing that illumination configuration for theframe period in which that same frame is to be displayed. However, itwill be appreciated that due to the processing effort involved indetermining an illumination configuration from one or more of suchframes, the illumination configuration often will not be ready forimplementation for display of the same frame(s) on which it was based.In such cases, the illumination configuration instead is employed forone or more subsequent frames, and the illumination configuration(s)determined from these subsequent frames are employed for one or morestill further subsequent frames and so forth. As such, reference toapplication of an illumination configuration for display of the sameframe from which the illumination configuration was determined shouldalso be understood to similarly describe application of an illuminationconfiguration for display of a subsequent frame, unless otherwise noted.

FIG. 3 illustrates an example display system 300 for implementing one ormore of the illumination configuration control techniques describedherein in accordance with some embodiments. The display system 300includes a rendering device 302 and a display device 304 connected by awired or wireless interconnect 305. The rendering device 302 includesany of a variety of devices used to generate video content, including anotebook computer, a desktop computer, a server, a game console, acompute-enabled smart-phone, and the like. The display device 304includes a digital display device to display video content, such as adigital television, computer monitor, portable device display, and thelike. Note that the rendering device 302 and the display device 304, insome implementations, are implemented in the same device, such as in thecase of a tablet computer, notebook computer, compute-enabled phone, andthe like. The rendering device 302 includes at least one memory 306, atleast one processor, such as a GPU 308 and a central processing unit(CPU) 310, and a display interface (IF) 312. The display device 304includes a display interface 314, a display controller 316, and adisplay matrix 318. The display interfaces 312, 314 include wired orwireless interconnect interfaces, such as HDMI interfaces, DisplayPortinterfaces, embedded DisplayPort (eDP) interfaces, and the like. Thedisplay controller 316 is implemented as one or more processors toexecute software instructions stored in memory (not shown), one or moreprogrammable logic components, one or more hardcoded logic components,or a combination thereof. The display matrix 318 includes atwo-dimensional array of pixels used to display a sequence of displayimages, and includes, for example, a light emitting diode (LED) matrix,an organic LED (OLED) matrix, a liquid crystal (LC) matrix, a matrix ofmovable mirrors for a digital light processing (DLP) display, or thelike.

As a general operational overview, the memory 306 stores one or moresets of executable software instructions to manipulate the CPU 310 andGPU 308 to render a video stream including a series of display framesand corresponding metadata and to transmit this video stream to thedisplay device 304 via the display interfaces 312, 314 and theinterconnect 305. At the display device 304, the display controller 316receives each display frame and corresponding metadata in turn, andprocesses the display frame for display in sequence at the displaymatrix 318 during a corresponding frame period.

The display device 304 is implemented as, for example, an emissive-typedisplay, a transmissive-type display, a reflective-type display, or ahybrid thereof. As illustrated by FIG. 4, a transmissive-type displaydevice 404 (one embodiment of the display device 304) implements thedisplay matrix 318 as an LC matrix 402 and a backlight 405 and thedisplay controller 316 is implemented as an LC controller 406 and abacklight controller 408. The LC matrix 402 implements an array of LCpixels 410, with each LC pixel 410 composed of one or more LC subpixelsrepresenting a corresponding color (e.g., red, green, and blue) of thepixel. In operation, each row of pixel data of a frame is fedsequentially to the LC controller 406, which selectively activates theLC pixels 410 at the corresponding row based on the pixel value for thecorresponding pixel in that row (e.g., pixel (X,Y) being the pixel valuefor the frame at column X and row Y). The backlight 405 is composed ofan array or other set of LEDs that are selectively activated to emitlight which is then polarized and selectively transmitted through eachLC pixel 410 of the LC matrix 402 based on the corresponding pixel valueused to selectively activate the LC pixel 410.

Thus, to “display” the frame, the backlight controller 408 uses one ormore LED drivers 414 to drive the LEDs 412, where the amount of current,voltage, or pulse shape (collectively, “power”) driven by the LEDdrivers 414, and thus the illumination intensity of the light emitted bythe LEDs 412, is controlled during each frame period via an illuminationcontrol (CTL) signal 416 controlled by the backlighting controller 408.As such, as the level or value of the illumination CTL signal 416 variesover a frame period, the backlighting emitted by the LEDs 412 variesaccordingly. As such, the illumination configuration for a frame periodis implemented in the transmissive-type display device 404 throughconfiguration of the level or value of the illumination CTL signal 416by the backlighting controller 408. That is, the backlighting controller408 implements any front illumination fill, illumination strobe, andback illumination fill for a frame period through corresponding controlof the illumination CTL signal 416.

Turning to FIG. 5, an emissive-type display device 504 (one embodimentof the display device 304) implements the display matrix 318 as an LEDmatrix 502 and the display controller 316 is implemented as an LEDcontroller 506. The LED matrix 502 implements an array of pixels 510,with each pixel 510 composed of one or more subpixels 512, eachrepresenting a corresponding color (e.g., red, green, and blue) of thepixel. Each subpixel is implemented as an LED or an OLED. In operation,each row of pixel data of a frame is fed sequentially to the LEDcontroller 506, which selectively activates the subpixels 512 of thepixels 510 at the corresponding row based on the pixel value for thecorresponding pixel in that row. Thus, to “display” the frame at thedisplay device 504, each subpixel 512 is driven by a correspondingdriver 514, where the power provided by the driver 514 to the subpixel512, and thus the illumination intensity of the light emitted by thesubpixel 512, is controlled by the combination of the associatedsubpixel value of the pixel represented by the subpixel 512 and thecurrent illumination level of the illumination configuration for theframe period as represented by an illumination CTL signal 516. In someembodiments, the subpixel value and the value of the illumination CTLsignal 516 are multiplied to generate a resulting value that controlsthe magnitude of current, voltage, or pulse shape supplied by the driver514. As such, the illumination CTL signal 516, representing the currentillumination configuration value at the corresponding point in time inthe frame period, acts to scale the illumination intensity of eachsubpixel up or down. For example, if the illumination CTL signal 516 isrepresented as an eight-bit value, then the illumination intensity ofthe subpixels 512 of the LED matrix 502 can be scaled up or down over256 steps. Accordingly, the display device 504 implements any frontillumination fill, illumination strobe, and back illumination fill for aframe period through corresponding control of the illumination CTLsignal 516.

Although FIGS. 4 and 5 illustrate embodiments of the display device 304in which the illumination intensity is globally scaled up or down duringa frame period in accordance with the same illumination configurationfor all pixels of the frame, in other embodiments the display device 304implements a regional illumination approach in which the display matrix318 is partitioned into a plurality of individually-controllableillumination regions. That is, each illumination region is separatelycontrollable so as to implement a region-specific illuminationconfiguration during a frame period. As illustrated by FIG. 6, thispartitioning is implemented in any of a variety of ways. Globalpartitioning 602 illustrates a configuration in which there is nopartitioning; that is, the entire display matrix 318 is a single, orglobal, illumination region 604. Row partitioning 612 illustrates aconfiguration of the display device 304 in which the display matrix 318is partitioned by row such that each subset of one or more rows of thedisplay matrix 318 is organized as a separate illumination region 614.Conversely, column partitioning 622 illustrates a configuration of thedisplay device 304 in which the display matrix 318 is partitioned bycolumn such that each subset of one or more columns of the displaymatrix 318 is organized as a separate illumination region 624. Gridpartitioning 632 illustrates a configuration of the display device 304in which the display matrix 318 is partitioned by row and by column suchthat the pixels are partitioned into a plurality of illumination regions634, each region including pixels from one or more rows and one or morecolumns. Other partitioning schemes can be employed to divide thedisplay matrix 318 into illumination regions that can be separatelycontrolled for illumination intensity purposes.

FIG. 7 illustrates the software stacks implemented at the renderingdevice 302 and the display device 304 to facilitate implementation ofone or more illumination configuration control techniques in accordancewith some embodiments. Software stack 702 is implemented in therendering device 302, and includes one or more video contentapplications 704, one or more operating system (OS) interfaces 706, asoftware developer kit (SDK)/OS interface 708, a graphics driver 710,and a display driver 712. The video content application 704 includes asoftware application that sources the video content to be rendered, suchas a gaming application, a virtual reality (VR) or augmented reality(AR) application, a video playback application, and the like. Drawinginstructions for a display image of this video content are provided tothe graphics driver 710 via the OS interface 706, whereupon the graphicsdriver 710 coordinates with the GPU 308 to render the correspondingdisplay frame, which is buffered in a frame buffer or other storagecomponent of the rendering device 302. The display driver 712 thenoperates to transmit the pixel data representative of the buffered frameon a row-by-row basis, along with associated metadata, to the displaydevice 304 via the interconnect 305.

In some embodiments, control of the illumination configuration for oneor more frame periods is primarily implemented by the rendering device302. In such embodiments, the software stack 702 includes a source-sideillumination control module 714 to implement one or more of theillumination configuration control techniques described herein. In theexample of FIG. 7, the source-side illumination control module 714 isshown as part of the graphics driver 710, but in other embodiments isimplemented elsewhere in the software stack 702. In these embodiments,the source-side illumination control module 714 determines anillumination configuration to implement for a corresponding set of oneor more frames and transmits a representation of this illuminationconfiguration to the display device 304 via, for example, a sidebandtransmission or as part of the metadata accompanying the pixel data ofthe frame. A display-side illumination control module 716 of a softwarestack 716 of the display device 304 receives this transmittedrepresentation of the illumination configuration and then configures thedisplay controller 316 to implement the illumination level(s) andsegment durations represented by the illumination configuration duringthe corresponding frame period. In other embodiments, control of theillumination configuration for frame periods is primarily implemented atthe display device 304 itself, in which case the display-sideillumination control module 716 determines and implements anillumination configuration directly at the display device based on theframe data being received from the rendering device 302.

Further, in some implementations, control of the illuminationconfiguration can be controlled or modified through user input. In someembodiments, this user input is received at the rendering device 302,and thus the software stack 702 includes a graphical user interface(GUI) 720 or other user interface to receive user input pertaining toillumination configuration and implement the user input accordingly. TheGUI 720 can be implemented, for example, as part of the graphics driver710 or, alternatively, as part of the video content application 704 orother software module of the software stack 702. In other embodiments inwhich the display device 304 controls the setting of the illuminationconfiguration, user input is received and implemented at a GUI 724 ofthe software stack 716 of the display device 304.

FIG. 8 illustrates a method 800 representing the general processemployed by the frame rate-based illumination output control techniques202 (FIG. 2) in accordance with some embodiments. For ease ofillustration, method 800 is described in an implementation context inwhich the source-side illumination control module 714 (FIG. 7) isresponsible for determining the illumination configuration settings tobe implemented. However, the process described below can be adapted forimplementation by the display-side illumination control module 718 usingthe guidelines provided herein.

At block 802, the GPU 308 renders or otherwise generates a frame in asequence of frames at the direction of the video content application 704and buffers the generated frame in a frame buffer or other storagecomponent at the rendering device 302. The display driver 712 thentransmits the buffered pixel data and metadata representative of thegenerated frame on a row-by-row basis to the display device 304 via theinterconnect 305. At block 804, for each row of pixel data received forthe frame being transmitted, the display controller 316 configures eachrow of pixels of the display matrix 318 to represent the correspondingpixel values of the received row of pixel data so that when illuminationof the frame at the display device 304 occurs during the associatedframe period, display light representative of the frame is emitted bythe display matrix 318, either directly via LED, OLED, plasma, or otheremissive pixel configurations, via selective backlight transmission byLC or other transmissive pixel configurations, or via selective lightreflection by digital light processing (DLP) or other reflective pixelconfigurations.

In parallel with the rendering, transmission, and pre-display matrixconfiguration process of blocks 802 and 804, the source-sideillumination control module 714 determines the parameters of theillumination configuration to be used for displaying the subject frame.This sub-process begins at block 806 with the illumination controlmodule 714 determining the current frame rate of the sequence of framesbeing generated. In some embodiments, the frame rate is fixed andrepresented by some control setting that is accessed or referenced bythe illumination control module 714. In other embodiments, the displaysystem 300 employs a variable frame rate, in which case the illuminationcontrol module 714 monitors the frame periods of one or more precedingdisplayed frames (as specified by a software-based or physical VSYNCsignal or a “frame completed” signal) to estimate the current framerate, or receives from the GPU 308 an indication of the current framerate being implemented by the GPU 308. From this, the illuminationcontrol module 714 estimates the duration of the next frame period via,for example, linear extrapolation, a polynomial best fit analysis,Kalman filtering, a machine learning process, and the like.

Based on the current frame rate, at block 808 the illumination controlmodule 714 determines whether the illumination configuration fordisplaying the frame is to include an illumination strobe, and if so, atleast one of the illumination level or duration to be used for theillumination strobe. Concurrently, at block 810 the illumination controlmodule 714 determines what illumination level(s) are to be implementedfor the front illumination fill and back illumination fill for theillumination configuration. The processes of blocks 808 and 810 isdescribed in greater detail below with reference to FIGS. 9-13.

With the illumination configuration determined, the illumination controlmodule 714 transmits a representation of the illumination configurationto the display device 304. This representation of the illuminationlevel(s), durations, and positions of the illumination configuration canbe implemented in any of a variety of formats and transmitted to thedisplay device 304 in any of a variety of ways, including as metadata orsideband data. To illustrate, assuming the display device 304 isconfigurable to provide an illumination configuration having a non-zerofront illumination fill, an illumination strobe, and a non-zero backillumination fill with fixed segment positions and durations, theillumination configuration can be represented as a control datastructure having three values, with a first value representing theillumination level for the illumination strobe, a second valuerepresenting the illumination level for the front illumination fill, anda third value representing the illumination level for the backillumination fill. In other embodiments with variable position andduration of the illumination strobe, the widths of at least two of thesegments is transmitted, and thus allowing derivation of the width andposition of the third segment in instances where the frame period isfixed or known. In other embodiments, the display controller 316includes a pre-populated table configured with different combinations offront illumination fill levels, back illumination fill levels, andstrobe illumination levels, and the representation of the determinedillumination configuration can include transmission of an index valuerepresenting a corresponding entry of the table at the displaycontroller 316.

In response to receiving the representation of the determinedillumination configuration, at block 814 the display-side illuminationcontrol module 718 configures the display controller 316 to control theillumination level of the display matrix 318 over the course of thecorresponding frame period so that the frame is illuminated by thedisplay matrix 318 and the resulting display light projected to theuser. For a transmissive-type display device (e.g., display device 404,FIG. 4), control of the illumination level of the display matrix 318over the corresponding frame period is achieved by controlling theillumination intensity, or light output, of the backlight 405 to reflectthe illumination level of the illumination configuration at thecorresponding point in time within the frame period. Reflective-typedisplay devices are controlled in a similar manner by controlling theillumination level of the reflected light source. For emissive-typedisplay devices (e.g., display device 504, FIG. 5), control of theillumination level of the display matrix 318 over the correspondingframe period is achieved by scaling each subpixel value based on anillumination control value that represents the illumination level of theillumination configuration at the corresponding point in time within theframe period so that the current, voltage, pulse shape, or other powerdriving the LED, OLED, or other emissive pixel scales with theillumination level within the illumination configuration. That is, thepower used to drive the emissive pixel is, in effect, representative ofa product of the subpixel value for that emissive pixel and a valuerepresenting the current illumination level in the illuminationconfiguration at that point in time in the frame period.

The flow of method 800 then returns to block 802 for the generation,buffering, transmission, and pre-display configuration of the nextframe. In some embodiments, the same illumination configuration isemployed for each frame generated within a sequence of two or moreframes (e.g., the sequence representing the frames generated betweenscene changes or the frames between two frames having substantiallydifferent brightness levels than their preceding frame), in which casethe sub-process of blocks 806, 808, 810, and 812 is only performed onceper sequence of frames. In other embodiments, an illuminationconfiguration is separately determined for each frame to be displayed,in which case the sub-process of blocks 806, 810, and 812 is performedanew for each generated frame.

Turning now to FIG. 9, an example technique for implementing theillumination output determination processes of blocks 808 and 810 ofmethod 800 is illustrated. In one embodiment, the illumination controlmodule 714 implements a output determination module 900 to obtainvarious input parameters 902, and from these input parameters 902,generate a representation 904 of the illumination configuration (e.g.,illumination configuration 906 or illumination configuration 908) to beimplemented for the illumination of a frame at the display device 304.

The frequency at which successive frames are displayed, that is, theframe rate, typically is a primary factor in the manifestation ofvarious display artifacts perceived by a user. At lower frame rates(e.g., at or below 60 frames-per-second (FPS)), most users are likely toperceive flicker caused by illumination strobes or other variations inthe average illumination level between frames. At higher frame rates(e.g., at or above 100 FPS), the flicker is likely to becomeimperceptible, but the timing of an illumination strobe potentially willresult in ghosting or tearing due to the row-by-row scan out andsettling time of pixels of the display device. Further, higher framerates can result in motion blur when constant illumination levels areused due to persistence of vision exhibited by most users. Accordingly,in at least one embodiment, the current frame rate (signal 910) isemployed as one of the input parameters 902 considered by the outputdetermination module 900 in determining the illumination output(s) (thatis, at least one of illumination level and duration) of the illuminationconfiguration at issue.

User input (signal 912) also can be employed by the output determinationmodule 900. To illustrate, the user may be less bothered by flicker, andthus provide user input indicating a lower threshold for employing anillumination strobe than would otherwise be set by the outputdetermination module 900. Conversely, another user may be more sensitiveto flicker, and thus provide user input that sets a higher threshold foremploying an illumination strobe. The use of user input as a factor insetting an illumination configuration is described in greater detailbelow with reference to FIG. 16.

The output determination module 900, in one embodiment, also utilizesone or more current operational parameters (signal 914) of the displaysystem 300 as input parameters 902 for determining the appropriateillumination levels of a resulting illumination configuration. Suchcurrent operational parameters include, for example, a level of ambientlight (which in turn is suggestive of a target average brightness of thedisplay device), a current temperature of the drivers for the backlight405 or the LED matrix 502 (which is indicative of whether the driversare at risk of being overloaded), a current operational state of the GPU308 (which indicate, for example, whether the next frame period is to bedelayed due to the GPU 308 being unable to render the correspondingframe in time), and the like.

In at least one embodiment, an illumination configuration is representedby at least three parameters: a strobe level value 916 representing anillumination level to employ for an illumination strobe (if activated)in the frame period, a front fill level value 918 representing anillumination level to employ for a front illumination fill preceding theillumination strobe, and a back fill level value 920 representing anillumination level to employ for a rear illumination fill following theillumination strobe. To illustrate, illumination configuration 906,having no front illumination fill, an illumination strobe atillumination level X1 and a back illumination fill at illumination X2could be represented by the tuple <0, X1, X2>, whereas illuminationconfiguration 908, having a front illumination fill 921 at illuminationlevel X3, an illumination strobe 923 at illumination level X5, and aback illumination fill 925 at illumination level X4 can be representedby the tuple <X3, X5, X4>.

As described below, the position of the illumination strobe can beadjusted, and thus the illumination configuration further can includeone or more segment position parameters 927 that specify the position ofone or more of the illumination strobe, the front illumination fill, andthe back illumination fill within the frame period. The “position” of acorresponding segment is represented, for example, as a start timefollowing start of the frame period and a width or other representationof duration of the segment. If the frame period is constant, thenspecification of the positions of any two of the illumination strobe,front illumination fill, and back illumination fill allows the positionof the remaining unspecified segment to be calculated. In the event thatan illumination strobe is not implemented in the illuminationconfiguration, the strobe level value 916 is set to zero, oralternatively, is set to the same value as either the front fill levelvalue 918 or the back fill level value 918, thereby in effect extendingthe duration of the corresponding illumination fill. In otherembodiments, the illumination level of an illumination strobe, ifactivated, is fixed or set, in which the representation 904 omits thestrobe level value 916, or includes, for example, a binary value toidentify whether to include an illumination strobe in the illuminationconfiguration. In other embodiments, the strobe duration also isadjustable based on frame rate or other input parameters 902, in whichcase the representation 904 would also include a strobe duration value915 representing the width or other duration representation of theillumination strobe (it will be appreciated that the strobe durationvalue 915 serves as a particular segment position parameter 927).

The values 916, 918, and 920 are presentable in any of a variety offormats. In some embodiments, each value is an absolute value setbetween the minimum and maximum thresholds for the correspondingillumination level. For example, each value 916, 918, and 920 can beimplemented as an eight-bit value, and thereby providing 256illumination level steps each. In other embodiments, some or all of thevalues 916, 918, and 920 are relative values. For example, the values918 and 920 can represent some percentage of the illumination valuerepresented by the strobe level value 916.

The output determination module 900, in one embodiment, identifies theillumination level(s) to be employed, the strobe duration to be employed(in implementations with variable strobe durations), and thepositions/durations of the strobe and front and back fills in anillumination configuration based on the input parameters 902 using anyof a variety of mechanisms or combinations thereof. In some embodiments,the output determination module 900 maintains one or more LUTs 922 orother tables that represent the relationship between a value for one ormore input parameters 902 and the corresponding illumination level(s),strobe duration, and segment position(s) to be implemented in theillumination configuration. To illustrate using a simple example basedon frame rate and in which the duration or positions of the segments arefixed, the LUT 922 could be configured as shown in Table 1:

TABLE 1 example LUT implementation FPS Strobe level Front fill levelBack fill level  <60 30 30 30 60-100 50 20 20 >100 70  0 40Thus, a frame rate of below 60 FPS results in a constant illuminationconfiguration (that is, the illumination level is constant over theentire frame period), a frame rate of 75 FPS would result inimplementation of an illumination strobe at an illumination level of 50,a front illumination fill at an illumination level of 20, and a backillumination fill at an illumination level of 20, and a frame rate of120 FPS would result in implementation of an illumination strobe at anillumination level of 70, a back illumination fill at an illuminationlevel of 40, and no front illumination fill (that is to say, a frontillumination fill at an illumination level of 0).

In other embodiments, the relationship between input parameter(s) 902and illumination level(s) and segment positions of an illuminationconfiguration is provided by one or more functions 924 or otherfunctional algorithms implemented in software code. For example, theexample relationship of the strobe level value 916 and FPS in Table 1could instead be represented as a function 924 in the format of:

${Strobe\_ level} = \left\{ \begin{matrix}{{30},} & {{FPS} < 60} \\{{50},} & {{60} \leq {FPS} \leq {100}} \\{{70},} & {{FPS} > {100}}\end{matrix} \right.$

In still other embodiments, the relationship between input parameter(s)902 and illumination level(s)/positions/durations of an illuminationconfiguration is provided using a learned model 926 developed using aneural network or other machine learning (ML) technique. To illustrate,in some embodiments, the user is presented with test video displayedusing different illumination configurations and the user's feedback onthe performance of each test video used as a training set for initialtraining of the learned model 926. Thereafter, the learned model can befurther refined based on user input that adjusts various illuminationconfiguration parameters to better suit the user's particularpreferences, based on observations of correlations between frame ratesor other various operational parameters and the effectiveness of thedisplay of frames using the resulting illumination configurations, andthe like.

The relationship between one or more operational parameters 902 andcorresponding illumination level(s), durations, and positions of theillumination configuration are configured in any of a number of manners.In some embodiments, the relationship is predefined by an OEM orsupplier of the graphics driver 710 or the GPU 308, and thus can beperiodically updated using firmware or software updates. For example, agraphics driver update release can include updated values for the LUT922. Further, in some embodiments, user input is used to originallycreate the representation of the relationship, or to adjustpreviously-determined values. For example, using the GUI 720 (FIGS. 7and 16), the user can set the FPS thresholds used to change illuminationlevel(s), to activate or deactivate use of an illumination strobe, tochange the illumination level(s) themselves, and the like. Stillfurther, as mentioned above, the relationship can be a dynamicrelationship as represented by, for example, a learned model that iscontinuously updated based on various training inputs.

Referring now to FIGS. 10 and 11, more detailed example relationshipsbetween frame rate (as an input parameter 902) and the illuminationparameters employed for an illumination configuration is shown. FIG. 10depicts two charts, chart 1000-1 and 1000-2, that illustrate specifiedrelationships between use and level/duration of an illumination strobeand a corresponding level of a surrounding fill based on frame rate, soas to achieve a more suitable balance between flicker mitigation andmotion blur mitigation than typically possible using only constant levelillumination or strobe-only illumination. This specified relationship,in some instances, is generalized as increasing the output of anillumination strobe and decreasing the magnitude of illumination fill asframe rate increases, and vice versa. With this approach, reduced oreliminated strobe emphasis at lower frame rates mitigates the potentialfor perceptible flicker, while increased strobe emphasis and decreasedfill emphasis at higher frame rates mitigates the potential for imageghosting and motion blur.

In the chart 1000-1, frame rate is represented by the abscissa, theleft-side ordinate represents illumination level for both a strobe and asurrounding fill, and the right-side ordinate represents the durationfor the strobe (fixed in this example). Line 1002 represents the strobeillumination level that varies between 0 and a maximum illuminationlevel STRB_MAX1 based on frame rate. Line 1004 represents theillumination fill level that varies between 0 and a maximum illuminationfill level FILL_MAX based on frame rate, where the surrounding filllevel represents an illumination fill that both precedes and follows anyillumination strobe present, or represents a constant illumination levelin the absence of an illumination strobe. Line 1006 represents theduration, or width, of the illumination strobe, which in this example isfixed at WIDTH_C (e.g., 4 ms) in this example once an illuminationstrobe is activated (at frame rate F_LOW). The left-side ordinaterepresents the scale of the illumination level for the surrounding filllevel, whereas the right-side ordinate represents the scale of theillumination level for the illumination strobe, when present.

As illustrated by lines 1002 and 1004, between a frame rate of 0 andF_LOW (e.g., 80 FPS), the illumination configuration relies entirely onthe surrounding fill to provide the illumination, with a constant fillillumination level of FILL_MAX. At a frame rate F_LOW, an illuminationstrobe is activated, with the strobe having a fixed duration of WIDTH_C(as illustrated by line 1006). Thus, between frame rate F_LOW and F_HIGH(e.g., 120 FPS), the strobe illumination level increases (substantiallylinearly in this example) while the illumination level of theillumination fill reduces (non-linearly in this example) from the levelFILL_MAX to zero. Thereafter, illumination is provided solely by theillumination strobe for frame rates between F_HIGH and F_MAX, with thestrobe illumination level decreasing (non-linearly in this example) tocompensate for the increasing strobe rate (due to increasing frame rate)so as to maintain a substantially constant illumination level. For eachstage, the relationship between fill level, strobe level, and strobeduration is configured so as to maintain a substantially constantillumination level, regardless of frame rate. Thus, as illustrated bythe stage between frame rate F_LOW and F_HIGH, as the strobeillumination level increases the fill illumination level decreases sothat the overall illumination output is constant. Likewise, betweenframe rate F_HIGH and F_MAX, while the illumination strobe is the onlyillumination source, the illumination level of the strobe decreases withincrease in frame rate in view of the increased number of strobes persecond so as to maintain a constant illumination per unit time.

Turning to chart 1000-2, in this chart frame rate is represented by theabscissa, the left-side ordinate represents illumination level for botha strobe and a surrounding fill, and the right-side ordinate representsthe duration for the strobe (variable in this example). Line 1012represents the strobe illumination level that varies between 0 and amaximum illumination level STRB_MAX2 based on frame rate. Line 1014represents the illumination fill level that varies between 0 and themaximum illumination fill level FILL_MAX based on frame rate, where thesurrounding fill level represents an illumination fill that bothprecedes and follows any illumination strobe present, or represents aconstant illumination level in the absence of an illumination strobe.Line 1016 represents the duration, or width, of the illumination strobe,which in this example varies based on frame rate up to a maximumduration WIDTH_MAX once an illumination strobe is activated (at framerate F_LOW). The left-side ordinate represents the scale of theillumination level for the surrounding fill level, whereas theright-side ordinate represents the scale of the illumination level forthe illumination strobe, when present.

As illustrated by lines 1012 and 1014, between a frame rate of 0 andF_LOW, the illumination configuration relies entirely on the surroundingfill to provide the illumination, with a constant fill illuminationlevel of FILL_MAX. At a frame rate F_LOW, an illumination strobe isactivated, with the strobe having a variable duration based on framerate (as illustrated by line 1014). Thus, between frame rate F_LOW andF_HIGH, both the strobe illumination level and the strobe durationincreases (substantially linearly in this example) while theillumination level of the illumination fill reduces (non-linearly inthis example) from the level FILL_MAX to zero. Thereafter, illuminationis provided solely by the illumination strobe for frame rates betweenF_HIGH and F_MAX, with the strobe duration constant at WIDTH_MAX and thestrobe illumination level decreasing (non-linearly in this example) tocompensate for the increasing strobe rate (due to increasing frame rate)so as to maintain a substantially constant illumination level. As withthe relationships represented by chart 1000-1, the relationships betweenfill level, strobe level, and strobe duration represented in chart1000-2 is configured so as to maintain a substantially constantillumination level, regardless of frame rate. Thus, as illustrated bythe stage between frame rate F_LOW and F_HIGH, as the strobe outputincreases the fill illumination output decreases so that the overallillumination output is constant. Likewise, between frame rate F_HIGH andF_MAX, while the illumination strobe is the only illumination source,the illumination level of the strobe decreases (at a constant strobeduration) with increase in frame rate in view of the increased number ofstrobes per second so as to maintain a constant illumination per unittime.

FIG. 11 illustrates various example illumination configurationsresulting from the relationship represented by chart 1000-1 of FIG. 10at different frame rates. Timing chart 1100 illustrates a sequence oftwo frame periods 1102-1 and 1102-2 used as a reference for therespective timings of the illustrated illumination configurations. Notethat the duration of the frame periods 1102-1 and 1102-2 are inverselyproportional to the frame rate being referenced in the correspondingillumination configuration.

Illumination configuration 1104 represents an illumination configurationdetermined from chart 1000-1 at a frame rate F1 that is below thethreshold frame rate F_LOW defining the lowest frame rate at which anillumination strobe is implemented (around 50 FPS, for example). Thus,as determined by the values of lines 1002 and 1004 at frame rate F1, forthe illumination configuration 1104 the surrounding fill level is set tothe maximum fill level FILL_MAX and the strobe illumination level is setto STROBE_MIN (e.g., 0), resulting in the illumination configuration1104 having a constant illumination level 1106 across each of the frameperiods 1102-1 and 1102-2. Displaying a sequence of frames at the framerate F1 using this illumination configuration thus exhibits reduced oreliminated flicker as there is no strobe present.

Illumination configuration 1108 represents an illumination configurationdetermined from chart 1000-1 at a frame rate F2 that is above thethreshold frame rate F_LOW but below a threshold frame rate F_HIGH atwhich the illumination strobe serves as the primary source ofillumination during the frame period. In the example of chart 1000-1,the strobe illumination level increases as frame rate increases fromF_LOW to F_HIGH as illustrated by the corresponding increasing segmentof line 1002 (recall again that in this example, strobe duration isconstant regardless of frame rate starting at frame rate F_LOW), whilethe surrounding fill illumination level decreases as frame rateincreases from F_LOW to F_HIGH as illustrated by the correspondingdecreasing segment of line 1004. Thus, as frame rate increases in thisrange, the strobe illumination level increases and the surrounding fillillumination level decreases commensurately. Accordingly, at the framerate F2, the resulting illumination configuration 1108 includes asurrounding fill 1110 having an illumination level Y2 (<FILL_MAX) and anillumination strobe 1112 having an illumination level Y3. Thus, at themiddle frame rates, including frame rate F2, the illuminationconfiguration employs a balanced blend of strobe magnitude and fillmagnitude, and thus achieving the reduced motion-blur benefit ofemploying an illumination strobe while also reducing the impact offlicker caused by the illumination strobe by surrounding the strobe withfill illumination, and thus reducing the net difference in illuminationlevel change caused by the illumination strobe. Moreover, by using amoderate level of fill in the frame periods 1102-1 and 1102-2, a givenaverage illumination for the frame periods is achievable with alower-level illumination strobe, and thus requiring a lower transientcurrent or other power output from the drivers of the backlight sourcesor emissive light pixels to implement the strobe, and enabling longerlife for light sources such as OLED that degrade over time at strongerdrive levels.

Illumination configuration 1114 represents an illumination configurationdetermined from chart 1000-1 at a frame rate F3 that is above thethreshold frame rate F_HIGH at which the illumination strobe serves asthe primary source of illumination during the frame period. In theexample of chart 1000-1, the strobe illumination level reaches itsmaximum level STROBE_MAX1 at F_HIGH and then decreases for all framerates above F_HIGH as illustrated by the corresponding downward slopedsegment of line 1002 so as to maintain a substantially constantillumination per unit time, while the surrounding fill illuminationlevel reaches its lowest illumination level FILL_MIN at frame rateF_HIGH. Thus, as frame rate increases in this range, the strobeillumination level gradually decreases with frame rate so as to maintaina constant illumination level in view of the increased frame rates (andthus increased strobe rate). Accordingly, at the frame rate F3, theresulting illumination configuration 1114 includes a surrounding fill1116 having an illumination level FILL_MIN (<Y2) and an illuminationstrobe 1118 having an illumination level Y4 (>Y3). Thus, at higher framerates (e.g., 100 FPS or above), including frame rate F3, theillumination configuration emphasizes use of an illumination strobe toreduce or elimination motion blur and deemphasizes surrounding fill asany flicker caused by the magnitude of change in illumination levelbetween the surrounding fill and the strobe is unlikely to be detectableby the typical user at such frame rates. Moreover, as with illuminationconfiguration 1108, by using a non-zero level of fill in the frameperiods 1102-1 and 1102-2, the illumination configuration 1114 canprovide a given average illumination for the frame periods with alower-level illumination strobe, which requires a lower transientcurrent or voltage from the drivers of the backlight sources or emissivelight pixels to implement the strobe. However, in implementations inwhich the drive current at maximum strobe levels is not likely tosubstantially reduce the operational lifetime of the drivers or thelight sources, the illumination configuration at the highest frame ratescan, for example, employ illumination strobes only (that is, set allsurrounding fill levels to zero).

As chart 1000-1 and the illumination configurations 1104, 1108, and 1114illustrate, in the illustrated representation between frame rate andillumination levels, the corresponding illumination configurationswitches from a constant illumination level configuration at lower framerates, to a blended balance of illumination strobe to illumination fillat intermediate frame rates (with the balance tilting toward theillumination strobe as frame rate increase), to an illuminationstrobe-dominant configuration at the highest frame rates. In thismanner, the illumination configuration can be tailored to address thevisual artifacts more likely to appear at a given frame rate.

FIGS. 12 and 13 illustrate another more detailed example relationshipbetween frame rate (as an input parameter 902, FIG. 9) and theillumination levels employed for an illumination configuration is shown.The chart 1200 of FIG. 12 represents a relationship between frame rate(abscissa), a strobe illumination level (line 1202), a front fillillumination level (line 1204), and a back fill illumination level (line1206). The left-side ordinate represents the scale of the illuminationlevel for the front and back fill illumination levels, whereas theright-side ordinate represents the scale of the illumination level foran illumination strobe, when present. In this example, the strobeduration is fixed for ease of illustration, and thus the strobe outputis varied based on variation of the strobe illumination level.

Chart 1200 represents an example implementation of a specifiedrelationship between use and level of an illumination strobe andcorresponding levels of front and back illumination fills based on framerate so as to achieve a more suitable balance between flicker mitigationand motion blur mitigation than typically possible using only constantlevel illumination or strobe-only illumination. This specifiedrelationship can be generalized as increasing the magnitude of anillumination strobe and decreasing the magnitude of illumination fill asframe rate increases, and vice versa. With this approach, reduced oreliminated strobe emphasis at lower frame rates mitigates the potentialfor perceptible flicker, while increased strobe emphasis and decreasedfill emphasis at higher frame rates mitigates the potential for imageghosting and motion blur. Moreover, with respect to the front and backillumination fills, the represented relationship further can begeneralized as reducing the front illumination fill level relative tothe back illumination fill level as frame rate increases.

FIG. 13 illustrates various example illumination configurationsresulting from the relationship represented by chart 1200 of FIG. 12 atdifferent frame rates. Timing chart 1300 illustrates a sequence of twoframe periods 1302-1 and 1302-2 used as a reference for the respectivetimings of the illustrated illumination configurations. Note that theduration of the frame periods 1302-1 and 1302-2 are inverselyproportional to the frame rate being referenced in the correspondingillumination configuration.

Illumination configuration 1304 represents an illumination configurationdetermined from chart 1300 at a frame rate F1 that is below thethreshold frame rate F_LOW defining the lowest frame rate at which anillumination strobe is implemented (around 50 FPS, for example). Thus,as determined by the values of lines 1202, 1204, and 1206 at frame rateF1, for the illumination configuration 1304 the front fill level and theback fill level both are set to the maximum fill level FILL_MAX and thestrobe illumination level is set to STROBE_MIN (e.g., 0), resulting inthe illumination configuration 1304 having a constant illumination level1306 across each of the frame periods 1302-1 and 1302-2. Displaying asequence of frames at the frame rate F1 using this illuminationconfiguration thus exhibits reduced or eliminated flicker as there is nostrobe present, and typically does not suffer from significant motionblur as motion blur is generally not readily detectable by the typicaluser as such low frame rates as motion judder typically is a moreprominent issue at lower frame rates.

Illumination configuration 1308 represents an illumination configurationdetermined from chart 1200 at a frame rate F2 that is above thethreshold frame rate F_LOW but below a threshold frame rate F_HIGH atwhich the illumination strobe serves as the primary source ofillumination during the frame period. In the example of chart 1200, thestrobe illumination level increases as frame rate increases from F_LOWto F_HIGH as illustrated by the corresponding increasing sloped segmentof line 1202, while the front and back fill illumination levels decreaseas frame rate increases from F_LOW to F_HIGH as illustrated by thecorresponding decreasing sloped segments of line 1204 and 1206. Thus, asframe rate increases in this range, the strobe illumination levelincreases and the surrounding fill illumination level decreasesproportionally. However, as also illustrated by chart 1200, the frontfill level decreases at a greater rate than the back fill level as framerate increases between the two thresholds F_LOW and F_HIGH, and thusresulting in the front illumination fill being deemphasized at a greaterrate than the back illumination fill as frame rate increases.Accordingly, at the frame rate F2, the resulting illuminationconfiguration 1308 includes a front illumination fill 1310 having anillumination level Y1 (<FILL_MAX), a back illumination fill 1312 havingan illumination level Y2 (>Y1) and an illumination strobe 1314positioned in between and having an illumination level Y3 (>Y2). Thus,at the middle frame rates, including frame rate F2, a resultingillumination configuration employs a balanced blend of strobe magnitudeand fill magnitude, and thus achieving the reduced motion-blur benefitof employing an illumination strobe while also reducing the impact offlicker caused by the illumination strobe by surrounding the strobe withfill illumination, and thus reducing the net difference in illuminationlevel change caused by the illumination strobe.

As described in more detail below, the row-by-row scan out of a frame tothe display device and the setup times to configure each pixel toreflect the pixel data being scanned in (particularly for LC-basedpixels) often results in the lower rows of pixels of the display matrix318 not yet being fully configured to reflect the current frame beinginput (and instead representing corresponding pixels from the previousframe scanned in or a transitional state) in the early part of the frameperiod used to display the frame being scanned in. As such, illuminationduring this early part of the frame period can result in display of ablended image composed of the upper pixel rows of the current frame andthe lower pixel rows of the previous frame—a phenomenon known as screentearing. The potential for screen tearing increases with frame rate asthe frame period shrinks relative to the scan in and setup time for aframe. Thus, by implementing a frame rate-fill illumination outputrelationship that increases the difference between the back illuminationfill and the front illumination fill as frame rate increases between theframe rate thresholds F_LOW and F_HIGH, less illumination is generatedduring the early part of the frame period as frame rate increases, andthus reducing the impact of any inadvertent illumination of a blendedframe during the early part of the frame period, while more illuminationis generated during the latter part of the frame period as frame rateincreases, and thus increasing the proportion of display lightrepresenting the display matrix 318 after all rows of pixels of thecurrent frame have been scanned in and have time to settle. Thus, asframe rate increases and with it the risk of screen tearing andghosting, the influence of display light generated in the early part ofa frame period is decreased and the influence of display light generatedin the later part of the frame period is increased, thereby scaling thescreen-tearing/ghosting mitigation as risk of screen tearing/ghostingincreases. This visibility of screen tearing also can be furtherdecreased by extending the illumination fill 1310 and delaying theillumination strobe 1314 and illumination fill 1312 until the scan outof the new pixels in the frame represented by frame period 1302-1 hascompleted, although such delays would add latency in exchange forreduced screen tearing.

Illumination configuration 1316 represents an illumination configurationdetermined from chart 1200 at a frame rate F3 that is above thethreshold frame rate F_HIGH at which the illumination strobe serves asthe primary source of illumination during the frame period. In theexample of chart 1200, the strobe illumination level reaches its maximumlevel STROBE_MAX at F_HIGH and then declines for all frame rates aboveF_HIGH as illustrated by the corresponding declining segment of line1202, while the front fill level declines (at a greater rate) for allframe rates above F_HIGH to F_FILL_MIN at frame rate F_MAX asillustrated by the corresponding declining segment of line 1204.Similarly, the back fill level continues to decline at a greater rateuntil it reaches the minimum level B_FILL_MIN at frame rate F_MAX. Thus,as frame rate increases in this range, at least one of the strobeillumination level, the front fill level or the back fill level declinesto maintain constant illumination. Accordingly, at the frame rate F3,the resulting illumination configuration 1316 includes a frontillumination fill 1318 having an illumination level Y4 (<Y1), a backillumination fill 1320 having an illumination level Y5 (<Y2) and anillumination strobe 1322 having an illumination level Y6 (<=STROBE_MAX).Thus, at higher frame rates (e.g., 120 FPS or above), including framerate F3, the illumination configuration emphasizes use of anillumination strobe to reduce or elimination motion blur anddeemphasizes surrounding fill as any flicker caused by the magnitude ofchange in illumination level between the surrounding fill and the strobeis unlikely to be detectable by the typical user at such frame rates.Moreover, as with illumination configuration 1108, by using a non-zerolevel of fill in the frame periods 1102-1 and 1102-2, the illuminationconfiguration 1114 can provide a given average illumination for theframe periods with a lower-level illumination strobe, which requires alower transient current from the drivers of the backlight sources oremissive light pixels to implement the strobe. Further, as describedabove, the deemphasis of front illumination fill in favor of backillumination fill at these highest frame rates reduces the impact of anyscreen tearing potentially likely to occur at such high frame rates.

It should be noted that although charts 1000 and 1200 illustrateexamples in which there are piecewise substantially linear relationshipsbetween frame rate and corresponding strobe and fill illumination levelsfor an illumination configuration for ease of description, in otherembodiments these relationships are non-linear, piecewise or otherwise.Further, rather than having only two frame rate thresholds and aconstant slope therebetween, the relationship between frame rate and acorresponding illumination level can have more than two inflectionpoints.

FIGS. 14 and 15 together illustrate the general process employed by thestrobe position control techniques 204 (FIG. 2) in accordance with someembodiments. In at least one embodiment, this process can be implementedas an extension of method 800 in which the strobe position is determinedin parallel with the strobe output determination process of block 808,and is described below in this context. Moreover, this process isdescribed in an implementation context in which the source-sideillumination control module 714 (FIG. 7) is responsible for determiningthe illumination configuration settings to be implemented. However, theprocess described below can be adapted for implementation by thedisplay-side illumination control module 718 using the guidelinesprovided herein.

Turning to FIG. 14, timing chart 1400 illustrates a sequence of twoframe periods 1402-1 and 1402-2 used as a reference for the respectivetimings of the illustrated strobe positioning process. As describedabove, at the start of a frame period 1402 (signaled by, for example,assertion of a VYSNC OR VBI), the pixel data for the frame to bedisplayed during the frame period is scanned out of the frame buffer ona row-by-row basis and transmitted to the display device (as representedby scan out line 1406), whereupon the display device 304 configures acorresponding row of the display matrix 318 based on the pixel data ofthe row of the frame currently being scanned in. The scan in of pixeldata at each row is not instantaneous, but rather requires some time forthe circuit elements representing the pixel to transition from a firststate representing the corresponding pixel from the previous frame to asecond state representing the corresponding pixel from the currentframe. This transition is particularly long, relatively, for LCDdisplays due to the time needed for the LCs of the pixels to changestate.

In timing chart 1400, time T1 represents the point in time in the frameperiod 1402-1 at which all rows of pixels for the current frame havebeen scanned in and the last row of pixels has settled to their newstates. The duration from frame period start to time T1 is relativelyindependent of frame rate, that is, it typically takes approximately thesame amount of time to fully scan in a frame into the display matrix 318regardless of the rate at which frames are transmitted when using avariable frame rate technique such as the Radeon™ FreeSync™ technologyavailable from Advanced Micro Devices, Inc. (otherwise the scan out timeis usually extended to fill the frame time by using a lower pixeltransfer rate). Thus, as frame rate increases (and frame period durationdecreases), the time needed to scan in a frame and allow sufficientsettling occupies an increasingly larger proportion of the frame periodduration.

The position of an illumination strobe in the illumination configurationfor a frame period has implications for display quality in view of thescan in and settling process. Starting an illumination strobe earlier inthe frame period can reduce latency, but risks introducing screentearing if the illumination strobe is activated before scan in andsettling have completed for the current frame. To illustrate,illumination configuration 1408 implements an illumination strobe 1410that is positioned to start at time T0 (<T1), and thus start whenapproximately the lower 40% of the rows of the current frame have notyet scanned in and settled. Accordingly, the illumination strobe 1410will result in illumination of a hybrid frame which has approximately60% of the upper rows of the current frame and approximately 40% of thelower rows of the previous frame (or some transitional states betweenthe lower rows of the previous frame and the lower rows of the currentframe). To avoid such artifacts, as illustrated by illuminationconfiguration 1412, an illumination strobe 1414 instead is positionedcloser to the end of the frame period, such as at time T2 (>T1). Thisallows the full frame to be scanned in and settled before initiating theillumination strobe, but introduces latency. Moreover, if the displaydevice 304 implements variable frame rates and if the next frame periodstarts early, the illumination strobe could not actually activate duringthe current frame period, but instead shift too far into the early partof the next frame period, thereby causing failure to display the currentframe and likely screen tearing for the next frame.

To achieve a suitable balance between risk of screen tearing of atoo-early illumination strobe and the latency and potential skippedframe display of a too-late illumination strobe, as illustrated byillumination configuration 1416, the strobe position control technique204 seeks to determine an appropriate position T(X) for the illuminationstrobe 1418 to be implemented in the illumination configuration 1416that reduces or eliminates overlap with the scan out and settling periodof the current frame while also reducing or eliminating the latencyintroduced by an overly-delayed strobe or skipped frame resulting from astrobe that is not positioned to activate before the start of the nextframe period.

The strobe position control technique 204 is implemented separately orin conjunction with the frame rate-based illumination control technique202 to set an illumination configuration. For example, in someimplementations, the display system 300 uses either a constant fillconfiguration or a strobe-only configuration, depending on frame rate.When in a strobe-only configuration, the strobe position controltechnique 204 can be implemented to suitably position the strobe withinthe frame period. In other implementations, the display system uses avarying fill level and varying strobe output based on frame rate, inwhich case the strobe position control technique 204 can be used toposition the strobe in the frame period along with one or both of afront illumination fill and a back illumination fill. However, it willbe appreciated that the position of the illumination strobe defines theduration of both the front illumination fill and the back illuminationfill, and thus the illumination levels set for the front and backillumination fills typically will be adjusted based on the duration ofeach fill in view of the strobe position that the average brightness ofthe frame period does not change depending on strobe position.

FIG. 15 illustrates a strobe positioning module 1500 that implements thestrobe position control technique 204 so as to determine a suitablestrobe position in accordance with some embodiments. The strobepositioning module 1500 receives one or more input parameters 1502, andfrom these, generate a representation 1504 of the position of anillumination strobe in the illumination configuration to be implementedfor the illumination of the frame at issue at the display device 304.For purposes of description, the position of the illumination strobe isdescribed as position within the frame period that the illuminationstrobe starts, or is activated. However, in other implementations, theposition refers to a position of a middle of the illumination strobe ora position of an end of the illumination strobe. The representation 1504of the strobe position can be expressed as a value that represents anabsolute timing reference, such as a particular number of millisecondsor clock cycles from the start of a frame period, or an absolute timingreference, such as a particular percentage of the overall frame period(e.g., a value of <0.25> indicating that the illumination strobe shouldbe initiated 25% of the way into a frame period). In at least oneembodiment, the representation 1504 of the strobe position is includedwith the other parameter values of the representation of an illuminationconfiguration transmitted to the display device 304 (or determined atthe display device 304 itself). For example, a representation of anillumination configuration can be provided as metadata or sideband datain the form of a tuple with the format: <[strobe position], [strobeduration], [strobe level], [front fill level], [back fill level]>.

In one embodiment, the strobe positioning module 1500 utilizes one ormore current operational parameters (signal 1506) of the display system300 as input parameters 1502 for determining the appropriate strobeposition in the corresponding illumination configuration. In particular,such operational parameters are representative of a current loading ofthe rendering device 302 and thus useful in predicting whether the nextframe period will start early, late, or on time. For example, thecurrent operating parameters can include a representation of a powerstate, representation of the complexity of the current frame beingrendered or the next frame to be rendered, or other indicator of thecurrent loading of the GPU 308, and thus indicate a probability as tothe timing of the rendering and transmission of the next frame.

As explained above, the frame period is inversely proportional to theframe period, and as the scan in and settle time of a frame isrelatively constant regardless of frame rate, and thus suitable timingof the position of the strobe within an illumination configurationbecomes more pernicious with the increase in frame rate, as the timingwindow between end of the scan in and settling period and the end of theframe period becomes narrow, as well as because the likelihood that thenext frame period will be delayed increases with an increase in framerate. Accordingly, in some embodiments, the current frame rate (signal1508) is utilized as one of the input parameters 1502 considered by thestrobe positioning module 1500 in determining a suitable strobeposition.

Sensitivity to screen tearing relative to sensitivity to latency,skipped frames, and judder often varies from user to user. For example,gamers often seek to minimize latency and accept the cost of morefrequent screen tearing, whereas a casual viewer of a video oftenprefers to avoid screen tearing where possible at the cost of increasedlatency. Accordingly, user input 1510 (one embodiment of signal 912,FIG. 9) also is employed as an input parameter 1502 by the strobepositioning module 1500. To illustrate, one user provides user inputindicating that earlier activation of the illumination strobe ispreferable to later activation of the illumination strobe in view ofreducing latency, whereas another user provides user input indicatingthat later activation of the illumination strobe is preferable so as tomitigate screen tearing. Also, different displays have differenttransition times from the previous pixel to the current pixel value,ranging from under 1 ms to many ms, especially with LC displays,affecting the visibility of tearing for a particular strobe position. Auser input, or parameters retrieved from the display or a database ofdisplays, facilitate varying the strobe position to better suit themonitor characteristics.

The relationship between the values of the input parameters 1502 and theresulting strobe position (as indicated by representation 1504) arerepresented at the rendering device 302 (or at the display device 304)using any of a variety of structures or mechanisms. In some embodiments,the relationship is represented using one or more LUTs 1510 or othertables, with each entry of the LUT 1510 being indexed based on one or acombination of input parameters and the corresponding entry containingthe representation 1504, or a value upon which the representation 1504is based. In other embodiments, the relationship between inputparameter(s) 1502 and strobe positions(s) of an illuminationconfiguration is provided by one or more functions 1512 or otherfunctional algorithms implemented in software code and executed as partof, for example, the graphics driver 710 at the rendering device 302 orexecuted at the display controller 316 of the display device 304.

In yet other embodiments, the relationship between input parameter(s)1502 and strobe positions for an illumination configuration is providedusing a learned model 1514 developed using a neural network or other MLalgorithm, which incorporates a history of some or all of the inputparameters 1502 to train and refine the learned model 1514. Toillustrate, in a variable frame rate implementation, the ML algorithmmonitors a history 1516 of previous frame periods, including theirstarts and whether they started early, late, or on time, and correlatethis information with various operating parameters, including GPUloading, power states, identification of the video content application704 being executed, sharing of resources among various guests, and thelike, and from this training input develop a learned model 1514 thatestimates the start time of the next frame period based on the currentoperational parameters received. With the next frame start timepredicted and with an understanding of the frame rate and otherconsiderations, the learned model 926 then can provide a strobe positionthat avoids activating after the next frame start time while alsoseeking to avoid activating during the scan in and settle period.

The LUT(s) 1510, function(s) 1512, or learned model 1514 used to definethe relationship between one or more operational parameters 1502 andcorresponding strobe positions of the illumination configuration can beconfigured in any of a variety of ways. For example, an OEM or othersupplier can run extensive modeling, simulations, or other testing todetermine a suitable strobe position of each of some or all possiblecombinations of values of the input parameters 1502, and populate theone or more LUTs 1510 or configure the one or more functions 1512accordingly. Further, in some embodiments, user input can be used tooriginally populate the one or more LUTs 1510 or configure the one ormore functions 1512, or to adjust previously-determined settingsrepresented by the one or more LUTs 1510 or one or more functions 1512.Still further, as explained above, the relationship in some instances isa dynamic relationship as represented by, for example, the learned model1514 that is continuously updated based on various training inputs,including the input parameters 1502 themselves.

As noted above, a user can provide user input that operates to eitherdefine some aspect of the relationship between various values one orinput parameters and corresponding values for one or more parameters ofan illumination configuration, including strobe positioning, strobeillumination level, strobe duration, and one or both of front and backfill levels. This input, in one embodiment, can be received via one ormore GUIs presented to the user, such as the GUI 720 implemented by thegraphics driver 710 at the rendering device (e.g., as a configurationGUI for the corresponding GPU 308) or the GUI 724 implemented at thedisplay device 304 (e.g., as an on-screen display (OSD)). Alternatively,in one embodiment the GUI 724 is present on a local connected devicesuch as a phone, or a completely remote location such as used forcontrolling a public billboard or movie theatre from a distant location.FIG. 16 illustrates an example GUI 1600 implemented as either GUI 720 orGUI 724 in accordance with some embodiments. The GUI 1600 typicallyincludes one or more panels to graphically represent the relationshipsbetween input parameters and corresponding parameters of theillumination configuration, as well as one or more panels that implementinput mechanisms to receive user input to set or adjust the illustratedrelationships in a corresponding manner. As an example, the GUI 1600 caninclude a relationship panel 1602 that displays a chart 1604 thatillustrates the current relationships between frame rate, the strobeillumination level, and the front and back fill levels. The relationshippanel 1602 further can display a timing chart 1606 that illustrates thecurrent setup for strobe positioning and strobe duration relative to thetiming of the frame period, including the timing of the frame scan inand setup phase. Correspondingly, in this example the GUI 1600 includesan input panel 1608 that is to receive user input that sets or modifiesone or more of the relationship parameters represented in chart 1604 ortiming chart 1606. One example includes input fields 1610 and 1612 toreceive user input setting or modifying the minimum illumination level(F_FILL_MIN) and maximum illumination level (F_FILL_MAX), respectively,for the front fill level of a resulting illumination configuration, aswell as input fields 1614 and 1616 to receive user input setting ormodifying the minimum illumination level (B_FILL_MIN) and maximumillumination level (B_FILL_MAX), respectively, for the back fill levelof the resulting illumination configuration.

Similarly, the input panel 1608 can include input fields to configureone or more parameters of an illumination strobe. To illustrate, in thedepicted example the relationship between strobe illumination level andframe rate is represented as a piecewise linear relationship (line 1618)with inflection points at frame rate S0 (which controls when use of anillumination strobe starts), at frame rate S1, and at frame rate S2(which controls when the illumination strobe reaches its maximumillumination level). Accordingly, the input panel 1608 can include inputfields 1620 and 1622 to receive user input setting or modifying theminimum illumination level (STROBE_MIN) and maximum illumination level(STROBE_MAX), respectively, of the illumination strobe, as well as inputfields 1624, 1626, 1268, 1630, 1632, and 1634 to receive user inputsetting or modifying the particular frame rate values for the inflectionpoints S0, S1, S2, as well as the strobe illumination level to be usedat each of the inflection points. The input panel 1608 further canfacilitate configuration of the strobe positioning through input fields1636 or 1638 or strobe duration through input fields 1640 or 1642.

The input fields of the input panel 1608 can be implemented as fill-infields, pull-down fields, and the like. In some instances, an absolutevalue is input to an input field. For example, the fields 1610, 1612,1614, 1616 each receives a value falling within a specified range, wherethe value input directly represents the corresponding illuminationlevel. As another example, the fields 1636 and 1640 controlling strobepositioning and strobe duration, respectively, receive valuesrepresenting a value in milliseconds. In other instances, a relativevalue is input to an input field. For example, input fields 1636, 1638can receive values that represent percentages of the duration of frameperiod, and thus are relative to the particular frame period at issue.Still further, rather than set a particular fixed value, the input panel1608 can provide the ability for a user to specify an adjustment to avalue that is dynamically determined by the display system 300. Toillustrate, in some implementations the relationship between GPUloading, frame rate, and starting position of an illumination strobe isdynamic and frequently updated by a learned model. One user finds thatthe learned model results in a relationship that causes the illuminationstrobe to occur somewhat early in the frame period and thus triggerscreen tearing instances more frequently than the user would otherwiseprefer. Accordingly, the user provides an adjustment value in the inputfield 1644 that adds a static adjustment to whatever strobe positionvalue is otherwise determined by the strobe positioning module 1500(FIG. 15). For example, input of a value of −0.4 causes the strobepositioning module 1500 to shift the strobe position back by 0.4milliseconds from the strobe position it otherwise would implement inthe absence of the user input in order to accommodate the user.

Moreover, rather than, or in addition to, using input fields to obtainuser input, in some embodiments one or more of the illustratedrelationships are user manipulable via a mouse cursor, touchscreen, orother input mechanism so as to allow the user to graphically manipulatedepicted graph or chart so as to achieve a desired relationship. Forexample, the inflection point S1 can be a graphical feature that theuser can move along the abscissa and ordinate of the chart 1604 via amouse cursor or touchscreen so as to change one or both of the framerate value and the strobe illumination level associated with theinflection point.

In addition to obtaining user input from a user of the display system300 to define or modify the relationships between various inputparameters and parameters of an illumination configuration to beimplemented for one or more frames, in some embodiments relationshipsdefined by other users of other display systems are used to set ormodify the relationships implemented by the display system 300. FIG. 17illustrates an example distributed system 1700 for providing suchdistributed relationship settings for an illumination configuration. Thedistributed system 1700 includes a remote server 1702 to which thedisplay system 300 is connected via a network 1703 (e.g., a wirelesslocal area network (WLAN), the Internet, etc.), as are one or moreremote display systems, such as remote display systems 1704-1, 1704-2,1704-3. Each of the remote display systems 1704 operate to generate anddisplay sequences of frames, and utilize the techniques described hereinto set illumination configurations for the display of the frames ofthese sequences.

In the course of operation, each remote display system 1704 sends anillumination configuration update 1706 to the remote server 1702. Theillumination configuration update 1706 includes a representation of arelationship between one or more input parameters and one or more inputconfiguration parameters as determined by the sending remote displaysystem 1704 in its course of operation. This takes the form of, forexample, one or more LUTs or other tables, descriptions of one or moresoftware functions, a copy of a learned model, and the like. Theillumination configuration update 1706 also includes informationpertaining to the status of the remote display system 1704 itself at thetime of generation of the relationship. This status informationincludes, for example, a serial number or model number of a component ofthe remote display system 1704, an identifier of the video contentapplication serving as the source of the frames associated with theillumination configuration update 1706, representations of one or morehardware specifications or operational status (e.g., GPU loading) of theremote display system 1704, and the like.

The remote server 1702 receives the periodic illumination configurationupdates 1706 from each of the remote display systems 1704 and integratesthem into one or more remotely-trained illumination configurationrelationships that represents a consensus or merging between variousinput parameters and the parameters for an output configuration thatshould result based on multiple systems' experiences. Theseremotely-trained illumination configurations then are categorized orindexed at the remote server 1702 using any of a variety of indicia,including hardware setup indicia, model indicia, identifiers of theparticular video content application associated with the relationshipand the like.

When preparing to execute the video content application 704, the displaysystem 300 queries the remote server 1702 by sending an illuminationconfiguration request 1708 to the remote server 1702. The illuminationconfiguration request 1708 includes identifiers of various relevantparameters of the display system 300, such as serial number, modelnumber, hardware specifications, identifier of the video contentapplication 704, current GPU loading, user preferences, and the like. Inresponse, the remote server 1702 identifies a suitable remotely-trainedillumination configuration relationship 1710 that most closely matchesthe relevant parameters provided in the illumination configurationrequest 1708 and transmits the identified remotely-trained illuminationconfiguration relationship 1710 to the display system 300 forimplementation. As with the illumination configuration updates 1706, theremotely-trained illumination configuration relationship 1710 isrepresented by, for example, one or more LUTs, one or more softwarefunctions, one or more learned models, and the like.

As an example, the display system 300 could include a gaming console setto execute a particular video game (one embodiment of the video contentapplication 704). The display system 300 thus sends an illuminationconfiguration request 1708 that identifies the model of the gamingconsole and the particular video game about to be played. The remoteserver 1702 then identifies a remotely-trained illuminationconfiguration relationship 1710 created as the result of feedback fromone or more of the remote display systems 1704 that are of the same orsimilar gaming console executing the same or similar video gameapplication, and thus allowing the display system 300 to rapidly tailorthe illumination configuration for displaying the frames generated bythe video game application to settings found useful by other players onother similar display systems without training or further user input.

Turning now to FIGS. 18-26, example implementations of the regionalillumination control techniques 206 for display region-by-regionillumination configuration control are described in greater detail. Asnoted above, these techniques employ a display device capable ofindividual illumination control on a per-region basis, where eachillumination region is, for example, a subset of columns of the pixelarray of the display device, a subset of rows of the pixel array, or ablock of pixels that represents pixels at the intersection of a subsetof one or more columns and a subset of one or more rows. These regionalillumination control techniques 206 are employed separately, or incombination with each other, as well as in combination with one or moreframe rate-based illumination control technique 202 or strobe positioncontrol technique 204 described above.

FIGS. 18 and 19 together illustrate an implementation of thebrightness-based regional illumination control technique 212 forcontrolling the illumination configuration for a given illuminationregion based on an evaluation of a brightness of a region of the framecorresponding to the illumination region. The method 1800 of FIG. 18illustrates the general flow of this technique in accordance with someembodiments, and is described with reference to the exampleimplementation represented in FIG. 19 in which the source-sideillumination control module 714 (FIG. 7) is responsible for determiningthe illumination configuration settings to be implemented by the displaydevice 304. However, the process described below can be adapted forimplementation by the display-side illumination control module 718 usingthe guidelines provided herein.

At block 1802, the GPU 308 renders or otherwise generates a frame 1902in a sequence of frames at the direction of the video contentapplication 704 and buffers the generated frame in a frame buffer 1904at the rendering device 302. At block 1804, the display driver 712 thentransmits the buffered pixel data and metadata representative of thegenerated frame 1902 on a row-by-row basis to the display device 304 viathe interconnect 305.

Concurrent with the frame generation and transmission processes ofblocks 1802 and 1804, the illumination control module 714 of thegraphics driver 710 initiates the process of determining an illuminationconfiguration for each illumination region of the display matrix 318. Inthe example of FIG. 19, the display matrix 318 is configured as agrid-based regional partitioning, having nine illumination regions1906-1 to 1906-9. However, while a nine-region example is illustrated,it will be appreciated that the display matrix 318 can be segmented intomore or fewer regions. In some instances, each pixel is represented asits own separate region, with each individual color element, orsub-pixel, analyzed for blur and flicker and illuminated separately.Accordingly, at block 1806 the illumination control module 714 selectsan illumination region and determines a brightness representation forthe region of the frame corresponding to the selected illuminationregion (this region of the frame referred to herein as the “frameregion”). To illustrate, in some embodiments, the graphics driver 710tasks the GPU 308 with generating a histogram 1812 for the frame region,with the histogram 1812 indicating the number of pixels within the frameregion having a corresponding pixel value, or falling within acorresponding pixel value range or “bucket.” The illumination controlmodule 714 then determines the brightness representation for the frameregion based on the histogram 1812. For example, the brightnessrepresentation indicates the number or proportion of pixels having apixel value greater than a threshold pixel value, an average pixel valuefor the pixels in the histogram 812, and the like. In other embodiments,the graphics driver 710 tasks the GPU 308 with generating an averagebrightness value 1814 for the frame region (e.g., akin to an averagepicture level (APL), but for that particular frame region rather thanthe entire frame), and the brightness representation for the frameregion thus includes, or is based on, this average brightness value.Note that, in some embodiments, the brightness representation isdetermined based on, the white luminance level, whereas in otherembodiments a separate brightness representation is determined for eachof the individual sub-colors and luminance. For ease of illustration,calculation of the brightness representation based on the whiteluminance level is utilized in the descriptions and examples below.

At block 1808, the illumination control module 714 either determines anillumination configuration for the illumination region or modifies anillumination configuration previously identified for the illuminationregion based on the brightness representation of the region. Toillustrate, in some embodiments, the illumination control module 714determines a default illumination configuration for the frame using oneor a combination of the techniques described above, and then theillumination control module 714 modifies the default illuminationconfiguration for each illumination region based on the brightnessrepresentation of the corresponding frame region to generate aparticular region-specific illumination configuration. For example, asdescribed below, the brightness representation can be used to increasethe strobe output and decrease a fill output from their default levels,or conversely decrease the strobe output and increase a fill output fromtheir default levels. In other embodiments, the brightnessrepresentation is used to select a particular illumination configurationfrom a set of predefined illumination configurations for use for thatregion.

The relationship between the brightness representation of a frame regionand corresponding illumination configuration for an illumination region(or modification to a default illumination configuration on a per-regionbasis) in one embodiment is implemented using one or more LUTs 1816, oneor more software functions 1818, or a learned model 1820 developed by anML algorithm trained on previous use and previous user input on varioussettings. For example, a LUT 1816 has a plurality of entries indexedbased on a corresponding brightness representation, or correspondingrange of brightness representations, and with each corresponding entrystoring a representation of a corresponding illumination configuration,including values for parameters such the particular front illuminationfill level, back illumination fill level, strobe level, strobe position,strobe duration, and the like. As another example, a default frame-wideillumination configuration is specified, and each entry of the LUT 1816includes an indication of a particular modification to the defaultillumination configuration, such as specifying an amount by which thestrobe level is to be decreased from the default strobe level and anamount by which the fill level is to be increased form the defaultstrobe level. As the flicker caused by an illumination strobe typicallyis more noticeable at brighter pixel levels and less noticeable atdarker pixel levels, in at least one embodiment, the relationshipbetween brightness representation and the corresponding region-specificillumination configuration is one that causes illumination strobe to bedeemphasized and fill level to be emphasized in brighter frame regionsand, conversely, causes illumination strobe to be emphasized and filllevel to be deemphasized in darker frame regions. To illustrate, for afirst frame region having a brightness representation above a highthreshold and thus indicating the first frame region has a high averagebrightness, the illumination control module 714 in this exampleimplements a constant level fill illumination configuration for theillumination region associated with the first frame region, whereas fora second frame region having a brightness representation below a lowthreshold and thus indicating the second frame region has a low averagebrightness, the illumination control module 714 in this exampleimplements a strobe-only illumination configuration for the illuminationregion associated with the second frame region. However, for a thirdframe region having a brightness representation between the low and highthresholds, the illumination control module 714 linearly or non-linearlyadjusts a strobe output and a fill output in opposite directions basedon the brightness representation so that the strobe output is emphasizedand the fill output deemphasized as average brightness increases withinthis range.

The illumination control module 714 repeats the process of blocks 1806and 1808 for each illumination region of the display matrix 318 so as todetermine a region-based illumination configuration (or region-basedillumination configuration modification) for each illumination region,and transmits a representation 1908 of the illumination configuration,or illumination configuration modification, for each illumination regionto the illumination control module 718 implemented at the displaycontroller 316 of the display device 304. For example, therepresentation 1908 can include a data structure having an entry foreach of illumination regions 1906-1 to 1906-9, with each entry storingvalues for the various parameters of the illumination configuration tobe implemented for that illumination region. Alternatively, the datastructure includes an entry representing a general illuminationconfiguration, and each region-associated entry includes data indicatinghow the general illumination configuration is to be modified to create aregions-specific illumination configuration for that region.

At block 1822, the display device 304 proceeds with display of the frame1902 during its corresponding frame period. As part of this process, theillumination control module 718 controls, via the display controller316, the illumination at each illumination region of the display matrix318 during the frame period for the frame 1902 so as to implement theillumination configuration for that illumination region as specified inthe per-region representation 1908. In other embodiments, theillumination control module 714 transmits one or more data structureswith values representing the brightness representation for each frameregion, and it is the illumination control module 718 that determines ormodifies an illumination configuration for each illumination regionbased on the received brightness representation for that region. In yetother embodiments, rather than receive the brightness representationsfrom the rendering device 302, the illumination control module 718 ofthe display device 304 determines the brightness representations foreach frame region (e.g., by generating a histogram or other per-regionbrightness representation) at the display device 304, and thendetermining a per-region illumination configuration based on thelocally-determined per-region brightness representations.

FIGS. 20-22 together illustrate an implementation of the motion-basedregional illumination control technique 214 for controlling theillumination configuration for a given illumination region based on anestimation of motion in the corresponding frame region. The method 2000of FIG. 20 illustrates the general flow of this technique in accordancewith some embodiments, and is described with reference to the exampleimplementation represented in FIG. 21 in which the source-sideillumination control module 714 (FIG. 7) is responsible for determiningthe illumination configuration settings to be implemented by the displaydevice 304. However, the process described below can be adapted forimplementation by the display-side illumination control module 718 usingthe guidelines provided herein.

At block 2002, the GPU 308 renders or otherwise generates a frame 2102in a sequence of frames at the direction of the video contentapplication 704 and buffers the generated frame in a frame buffer 2104at the rendering device 302. At block 2004, the display driver 712 thentransmits the buffered pixel data and metadata representative of thegenerated frame 2102 on a row-by-row basis to the display device 304 viathe interconnect 305.

Concurrent with the frame generation and transmission processes ofblocks 2002 and 2004, the illumination control module 714 of thegraphics driver 710 initiates the process of determining an illuminationconfiguration for each illumination region of the display matrix 318based on motion estimations for each corresponding frame region. In theexample of FIG. 21, the display matrix 318 is configured as a grid-basedregional partitioning, having nine illumination regions 2106-1 to2106-9. Accordingly, at block 2006 the illumination control module 714selects a region of the current frame and determines motion estimationregion representation for the frame region corresponding to the selectedregion.

As is well understood in the art, motion estimation is a process ofdetermining the transformation of a previous frame into the currentframe. Typically, motion estimation reflects a comparison of the currentframe to the preceding frame or other previous reference frame, anddetermining motion vectors that represent the movement of objects orpixel blocks from their positions in the reference frame to theirpositions in the current frame. The GPU 308 can use any of a variety ofwell-known or proprietary techniques to determine the motion vectorsrepresenting the motion for the current frame, including Full Search andother block-matching techniques, phase-correlation techniques,frequency-matching techniques, pixel recursive techniques, and opticalflow techniques. From the motion vectors determined for the frame, theGPU 308 or other component of the rendering device 302 then determines amotion estimate representation for each of the frame regionscorresponding to illumination regions 2106-1 to 2106-9 based on themotion vectors that have an origin in the subject region of the currentframe, on the motion vectors that have a destination in the subjectregion of the current frame, or a combination thereof. To illustrate, inone embodiment, the GPU 308 tallies the number of macroblocks or codingtree units (CTUs) in the frame region that have a motion vector (or amotion vector above a certain magnitude threshold to filter jitter) andthen determines a motion estimate representation for this frame regionbased on this number. As another example, in another embodiment the GPU308 generates an average motion vector magnitude or other statisticalevaluation from the motion vectors of the macroblocks or CTUs in theframe region and generate the motion estimation representation for thisframe region based on this statistical evaluation.

At block 2008, the illumination control module 714 either determines anillumination configuration for the illumination region or modifies anillumination configuration previously identified for the region based onthe motion estimate representation of the corresponding frame region. Toillustrate, in some embodiments, the illumination control module 714determines a default illumination configuration for the frame using oneor a combination of the techniques described above, and then theillumination control module 714 modifies the default illuminationconfiguration for each illumination region based on the motion estimaterepresentation of the frame region to generate a particularregion-specific illumination configuration. In other embodiments, themotion estimation representation is used to select a particularillumination configuration from a set of predefined illuminationconfigurations for use for that region.

The relationship between the motion estimation representation for aframe region and corresponding illumination configuration for acorresponding illumination region (or modification to a defaultillumination configuration on a per-region basis) can be implementedusing one or more LUTs 2016, one or more software functions 2018, or alearned model 2020 developed by an ML algorithm trained on previous useand previous user input on various settings. For example, a LUT 2016 hasa plurality of entries indexed based on a corresponding motionestimation representation, or corresponding range of motion estimationrepresentations, and with each corresponding entry storing arepresentation of a corresponding illumination configuration, includingvalues for parameters such the particular front illumination fill level,back illumination fill level, strobe level, strobe position, strobeduration, and the like. As another example, a default frame-wideillumination configuration is specified, and each entry of the LUT 2016includes an indication of a particular modification to the defaultillumination configuration, such as specifying an amount by which thestrobe level is to be decreased from the default strobe level and anamount by which the fill level is to be increased form the defaultstrobe level.

With regard to the relationship between motion estimation for a frameregion and illumination configuration control, it is noted that frameregions having relatively low motion are less likely to suffer frommotion blur, and thus implementation of a pronounced illumination strobefor the corresponding illumination region is likely unnecessary formotion blur mitigation, but could introduce flicker depending on theframe rate without any benefit. Conversely, frame regions havingrelatively high motion are likely to exhibit motion blur, and for suchregions an illumination strobe is emphasized. Accordingly, in at leastone embodiment, the relationship implemented by the illumination controlmodule 714 to set or modify an illumination configuration for theillumination region generally provides for increasing strobe emphasisand decreasing fill emphasis with an increase in motion estimation, andconversely, for decreasing strobe emphasis and increasing fill emphasiswith a decrease in motion estimation for the frame region. Thus, for ascheme in which a frame-wide default or general illuminationconfiguration is modified on a region-by-region basis, the illuminationcontrol module 714 can use the motion estimate representation todecrease the strobe output and increase a fill output from their defaultlevels for a frame region identified as containing relatively littlemotion, or conversely increase the strobe output and decrease a filloutput from their default levels for a region identified as containingrelatively high motion. To illustrate, for a first frame region having amotion estimation representation below a low threshold and thusindicating the first frame region has a very low or zero motionestimation, the illumination control module 714 in one embodimentimplements a constant level fill illumination configuration for theillumination region corresponding to the first frame region, whereas fora second frame region having a motion estimation representation above ahigh threshold and thus indicating the second frame region has a veryhigh motion estimation, the illumination control module 714 in oneembodiment implements a strobe-only illumination configuration for theillumination region corresponding to the second frame region. However,for a third frame region having a motion estimation representationbetween the low and high thresholds, the illumination control module 714linearly or non-linearly adjusts one or both of a strobe level andduration and a fill level in opposite directions based on the motionestimation representation so that the strobe output is emphasized andthe fill output deemphasized as motion estimation increases within thisrange.

The illumination control module 714 repeats the process of blocks 2006and 2008 for each frame region of the frame corresponding to anillumination region of the display matrix 318 so as to determine aregion-based illumination configuration (or region-based illuminationconfiguration modification) for each illumination region, and transmitsa representation 2108 of the illumination configuration, or illuminationconfiguration modification, for each illumination region to theillumination control module 718 implemented at the display controller316 of the display device 304. As similarly described above, therepresentation 2108 can include a data structure having an entry foreach of illumination regions 2106-1 to 2106-9, with each entry storingvalues for the various parameters of the illumination configuration tobe implemented for that illumination region. Alternatively, the datastructure includes an entry representing a general illuminationconfiguration, and each region-associated entry includes data indicatinghow the general illumination configuration is to be modified to create aregions-specific illumination configuration for that illuminationregion.

At block 2022, the display device 304 proceed with display of the frame2102 during its corresponding frame period. As part of this process, theillumination control module 718 controls, via the display controller316, the illumination at each illumination region of the display matrix318 during the frame period for the frame 2102 so as to implement theillumination configuration for that illumination region as specified inthe per-region representation 2108. In other embodiments, theillumination control module 714 transmits one or more data structureswith values representing the motion estimation representation for eachillumination region, and it is the illumination control module 718 thatdetermines or modifies an illumination configuration for eachillumination region based on the received motion estimationrepresentation for that region.

To illustrate an example of the method 2000, FIG. 22 depicts an examplesequence 2200 of two frames 2202-1 and 2202-2, with frame 2202-1preceding frame 2202-2 in display order. Each of the frames 2202-1 and2202-2 is partitioned into a 3×3 grid of frame regions, with each frameregion corresponding to an independently-controlled illumination regionof the display matrix 318. In this example, the sequence 2200 representsmotion of pixel content representing an automobile object 2204 as ittravels horizontally, with the bulk of the pixel content originating ina region 2206 of frame 2202-1 and appearing in a frame region 2208 offrame 2202-2. Assume, for this example, that there is no other motion ofsignificance in the sequence. Thus, for frame 2202-2, frame regions 2206and 2208 exhibit considerable motion from the preceding frame 2202-1,and thus frame regions 2206 and 2208 for frame 2202-2 would be assignedmotion estimate representations with high values representingconsiderable motion, whereas the remaining frame regions of the frame2202-2 would be assigned motion estimate representations with low valuesrepresenting low or zero motion. Accordingly, for each of frame regions2206 and 2208, the illumination control module 714 would generate aregion-specific illumination configuration that provides a prominentillumination strobe and deemphasized illumination fill (including noillumination fill) so as to mitigate the motion blur that otherwisepotentially would occur in the two corresponding illumination regionswith a less emphasized illumination strobe. For frame regions 2210 and2210 that contain a slight amount of motion and thus are represented bysmall, non-zero motion estimate representations, the illuminationcontrol module 714 would generate a region-specific illuminationconfiguration that balances the strobe output and the fill output basedon the motion estimation representation for the frame region so as tobalance the risk of motion blur versus flicker in the associatedillumination region. For each of the remaining regions, the illuminationmodule 714 would generate a region-specific illumination configurationthat provides a prominent illumination fill and deemphasizedillumination strobe (including no strobe, or a constant-level fillillumination) so as to mitigate the flicker that otherwise potentiallywould occur in these illumination regions if a more prominent strobewere to be used.

FIGS. 23-26 together illustrate an implementation of the foveatedregional illumination control technique 216 for controlling theillumination configuration for a given illumination region based onwhether the illumination region is a foveal region or a peripheralregion. In order to implement such a technique, the display system 300utilizes a gaze tracking subsystem 2300 for determining the current gazeposition of a user, as illustrated by FIG. 23. In at least oneembodiment, the gaze tracking subsystem 2300 utilizes one or more lightsources 2302 (e.g., infrared (IR) LEDs) co-located with the displaymatrix 318 of the display device 304 to illuminate one or both eyes 2304of a user, as well as one or more imaging cameras 2306 directed towardthe position of the eyes 2304 so as to capture imagery of the user'seyes 2304 as illuminated by the light sources 2302. A gaze trackingmodule 2308 analyzes the captured imagery to determine a current gazedirection 2310 of the eyes 2304 using any of a variety of well-known orproprietary gaze tracking techniques, and from a known geometricalconfiguration between the position of the imaging camera 2306, theposition of the display matrix 318, the position of the user's eyes2304, and the gaze direction 2310, triangulates the current gazeposition 2312; that is, the point on the display matrix 318 that is thetarget of the user's current foveal view. The gaze tracking module 2308then provides a gaze position representation 2314 of the current gazeposition 2312 to the graphics driver 710, the GPU 308, or othercomponent of the rendering device 302. The gaze position representation2314 can include, for example, an (X,Y) coordinate pair identifying the(X,Y) position of the current gaze position 2312 relative to the pixelsof the display matrix 318, a value identifying the illumination regionof the display matrix 318 that contains the location of the current gazeposition 2312, and the like.

Turning now to FIG. 24, the method 2400 of FIG. 24 illustrates thegeneral flow of the foveated regional illumination control technique 216in accordance with some embodiments, and is described with reference tothe example implementation represented in FIG. 25 in which thesource-side illumination control module 714 (FIG. 7) is responsible fordetermining the illumination configuration settings to be implemented bythe display device 304. However, the process described below can beadapted for implementation by the display-side illumination controlmodule 718 using the guidelines provided herein.

At block 2402, the GPU 308 renders or otherwise generates a frame 2502in a sequence of frames at the direction of the video contentapplication 704 and buffers the generated frame in a frame buffer 2504at the rendering device 302. At block 2404, the display driver 712 thentransmits the buffered pixel data and metadata representative of thegenerated frame 2502 on a row-by-row basis, a column-by-column basis, ablock-by-block basis, or some other pattern basis, to the display device304 via the interconnect 305.

Concurrent with the frame generation and transmission processes ofblocks 2402 and 2404, the illumination control module 714 of thegraphics driver 710 initiates the process of determining an illuminationconfiguration for each illumination region of the display matrix 318based on the current gaze position 2312 and its relationship to theillumination regions region. In the example of FIG. 25, the displaymatrix 318 is configured as a grid-based regional partitioning, having a5×5 arrangement of illumination regions 2501-1 to 2501-25. At block2406, the gaze tracking subsystem 2300 determines the current gazeposition 2312 and provides the corresponding gaze positionrepresentation 2314 to the illumination control module 714. At block2408, the illumination control module 714 classifies each of theillumination regions 2501-1 to 2501-25 based on the location of thecurrent gaze position 2312 represented by the gaze positionrepresentation 2314 relative to the illumination region at issue. Insome embodiments, the illumination control module 714 implements a twotier approach in which each illumination region is classified as eithera foveal region or a peripheral region based on distance of the regionfrom the current gaze position 2312. In this case, the illuminationregion containing the current gaze position 2312 is designated as thefoveal region and all of the remaining illumination regions aredesignated as peripheral regions. In other embodiments, more than twotiers of classification are implemented based on distance from thecurrent gaze position 2312. For example, in one embodiment theillumination control module 714 implements a three tier approach inwhich the illumination region containing the current gaze position 2312is classified as the foveal region, the illumination regions immediatelyadjacent to the foveal region are classified as intermediate regions,and the remaining illumination regions are classified as peripheralregions. Other classification schemes can be implemented using theguidelines provided herein.

At block 2410, the illumination control module 714 either determines anillumination configuration for a selected illumination region ormodifies an illumination configuration previously identified for theselected illumination region based on the classification of the selectedregion. To illustrate, in some embodiments, the illumination controlmodule 714 determines a default illumination configuration for the frameusing one or a combination of the techniques described above, and thenthe illumination control module 714 modifies the default illuminationconfiguration for each illumination region based on the classificationof the region to generate a particular region-specific illuminationconfiguration. In other embodiments, the classification of the region isused to select a particular illumination configuration from a set ofpredefined illumination configurations for use for that region.

In at least one embodiment, the relationship between the gaze-basedclassification for an illumination region and corresponding illuminationconfiguration for the illumination region (or modification to a defaultillumination configuration on a per-region basis) are implemented usingone or more LUTs 2412, one or more software functions 2414, or a learnedmodel 2416 developed by an ML algorithm trained on previous use andprevious user input on various settings. For example, a LUT 2412 has aplurality of entries indexed based on a corresponding gaze-basedclassification, with each corresponding entry storing a representationof a corresponding illumination configuration, including values forparameters such the particular front illumination fill level, backillumination fill level, strobe level, strobe position, strobe duration,and the like. As another example, a default frame-wide illuminationconfiguration is specified, and each entry of the LUT 2412 includes anindication of a particular modification to the default illuminationconfiguration, such as specifying an amount by which the strobe level isto be decreased from the default strobe level and an amount by which thefill level is to be increased form the default strobe level.

In the human visual system, a user's peripheral vision typically is moresusceptible to noticing flicker than the user's foveal vision.Conversely, reduced acuity in a user's peripheral vision typicallycauses the user to be less susceptible to noticing motion blur in theperipheral vision, and more likely to notice motion blur in the fovealvision. Accordingly, in at least one embodiment, the relationshipimplemented by the illumination control module 714 to set or modify anillumination configuration for the illumination region generallyprovides for increased strobe emphasis and decreased fill emphasis foran illumination region classified as a foveated region, and conversely,for decreased strobe emphasis and increased fill emphasis forillumination regions classified as peripheral regions. Further, inembodiments in which an intermediate region classification is utilized,the relationship provides for a balance between strobe output and filloutput for regions identified as such. Thus, for a scheme in which aframe-wide default or general illumination configuration is modified ona region-by-region basis, the illumination control module 714 can usethe gaze-based classification for the illumination region to decreasethe strobe output and increase a fill output from their default levelsfor an illumination region identified as a peripheral region, orconversely increase the strobe output and decrease a fill output fromtheir default levels for a region identified the foveal region. Further,for an illumination region classified as an intermediate region, thegeneral illumination configuration is employed without modification inthis example.

The illumination control module 714 repeats the process of block 2410for each illumination region of the display matrix 318 so as todetermine a region-based illumination configuration (or region-basedillumination configuration modification) for each illumination region,and transmits a representation 2508 of the illumination configuration,or illumination configuration modification, for each illumination regionto the illumination control module 718 implemented at the displaycontroller 316 of the display device 304. As similarly described above,the representation 2508 can include a data structure having an entry foreach of illumination regions 2501-1 to 2501-25, with each entry storingvalues for the various parameters of the illumination configuration tobe implemented for that illumination region. Alternatively, the datastructure includes an entry representing a general illuminationconfiguration, and each region-associated entry includes data indicatinghow the general illumination configuration is to be modified to create aregions-specific illumination configuration for that illuminationregion.

At block 2418, the display device 304 proceeds with display of the frame2502 during its corresponding frame period. As part of this process, theillumination control module 718 controls, via the display controller316, the illumination at each illumination region of the display matrix318 during the frame period for the frame 2502 so as to implement theillumination configuration for that illumination region as specified inthe per-region representation 2508. In other embodiments, theillumination control module 714 transmits one or more data structureswith values representing the gaze-based classification for eachillumination region, and it is the illumination control module 718 thatdetermines or modifies an illumination configuration for eachillumination region based on the received gaze-based classification forthat region.

To illustrate an example of the method 2400, FIG. 26 depicts twodifferent frames 2602-1 and 2602-2. Each of the frames 2602-1 and 2602-2is partitioned into a 5×5 grid of frame regions, with each frame regioncorresponding to an independently-controlled illumination region 2501 ofthe display matrix 318. Frame 2602-1 illustrates the two-tierclassification approach described above. In this example, the currentgaze position (identified by icon 2604) is located in the areaassociated with illumination region 2501-17 (see FIG. 25), and thusillumination region 2501-17 is classified as the foveal region and theremaining illumination regions 2501-1 to 2501-16 and 2501-18-2501-25 areclassified as peripheral regions. Accordingly, the region-specificillumination configuration employed by the display device 304 for theillumination region 2501-17 would be set or modified to emphasize use ofan illumination strobe and deemphasize use of illumination fill, andwhile the other illumination regions would have region-specificillumination configurations that would be set or modified to deemphasizestrobe use and emphasize fill use.

Frame 2602-2 illustrates the two-tier classification approach alsodescribed above. In this example, the current gaze position (identifiedby icon 2604) is located in the area associated with illumination region2501-13 (see FIG. 25), and thus illumination region 2501-13 isclassified as the foveal region. Illumination regions 2501-7, 2501-8,2501-9, 2501-12, 2501-14, 2501-17, 2501-18, and 2501-19 are immediatelyadjacent to the illumination region 2501-13 and thus are classified asintermediate regions, and the remaining illumination regions areclassified as peripheral regions. Accordingly, in this example, theregion-specific illumination configuration employed by the displaydevice 304 for the foveal region would be set or modified to emphasizeuse of an illumination strobe and deemphasize use of illumination fill,the region-specific illumination configurations for the peripheralregions would be set or modified to deemphasize strobe use and emphasizefill use, and the region-specific illumination configurations for theintermediate regions could, for example, default to a general frame-wideillumination configuration determined using one of the otherillumination configuration control techniques described above.

In some embodiments, the apparatus and techniques described above areimplemented in a system including one or more integrated circuit (IC)devices (also referred to as integrated circuit packages or microchips),such as one or more of the components of the display system 300described above with reference to FIGS. 1-26. Electronic designautomation (EDA) and computer aided design (CAD) software toolstypically are used in the design and fabrication of these IC devices.These design tools typically are represented as one or more softwareprograms. The one or more software programs include code executable by acomputer system to manipulate the computer system to operate on coderepresentative of circuitry of one or more IC devices so as to performat least a portion of a process to design or adapt a manufacturingsystem to fabricate the circuitry. This code can include instructions,data, or a combination of instructions and data. The softwareinstructions representing a design tool or fabrication tool typicallyare stored in a computer readable storage medium accessible to thecomputing system. Likewise, the code representative of one or morephases of the design or fabrication of an IC device are stored in andaccessed from the same computer readable storage medium or a differentcomputer readable storage medium.

A computer readable storage medium includes any non-transitory storagemedium, or combination of non-transitory storage media, accessible by acomputer system during use to provide instructions and/or data to thecomputer system. Such storage media can include, but is not limited to,optical media (e.g., compact disc (CD), digital versatile disc (DVD),Blu-Ray disc), magnetic media (e.g., floppy disc, magnetic tape, ormagnetic hard drive), volatile memory (e.g., random access memory (RAM)or cache), non-volatile memory (e.g., read-only memory (ROM) or Flashmemory), or microelectromechanical systems (MEMS)-based storage media.The computer readable storage medium is, for example, embedded in thecomputing system (e.g., system RAM or ROM), fixedly attached to thecomputing system (e.g., a magnetic hard drive), removably attached tothe computing system (e.g., an optical disc or Universal Serial Bus(USB)-based Flash memory), or coupled to the computer system via a wiredor wireless network (e.g., network accessible storage (NAS)).

In some embodiments, certain aspects of the techniques described aboveare implemented by one or more processors of a processing systemexecuting software. The software includes one or more sets of executableinstructions stored or otherwise tangibly embodied on a non-transitorycomputer readable storage medium. The software can include theinstructions and certain data that, when executed by the one or moreprocessors, manipulate the one or more processors to perform one or moreaspects of the techniques described above. The non-transitory computerreadable storage medium can include, for example, a magnetic or opticaldisk storage device, solid state storage devices such as Flash memory, acache, random access memory (RAM) or other non-volatile memory device ordevices, and the like. The executable instructions stored on thenon-transitory computer readable storage medium are implemented insource code, assembly language code, object code, or other instructionformat that is interpreted or otherwise executable by one or moreprocessors.

Note that not all of the activities or elements described above in thegeneral description are required, that a portion of a specific activityor device may not be required, and that one or more further activitiescan be performed, or elements included, in addition to those described.Still further, the order in which activities are listed are notnecessarily the order in which they are performed. Also, the conceptshave been described with reference to specific embodiments. However, oneof ordinary skill in the art appreciates that various modifications andchanges can be made without departing from the scope of the presentdisclosure as set forth in the claims below. Accordingly, thespecification and figures are to be regarded in an illustrative ratherthan a restrictive sense, and all such modifications are intended to beincluded within the scope of the present disclosure.

Benefits, other advantages, and solutions to problems have beendescribed above with regard to specific embodiments. However, thebenefits, advantages, solutions to problems, and any feature(s) that cancause any benefit, advantage, or solution to occur or become morepronounced are not to be construed as a critical, required, or essentialfeature of any or all the claims. Moreover, the particular embodimentsdisclosed above are illustrative only, as the disclosed subject mattercan be modified and practiced in different but equivalent mannersapparent to those skilled in the art having the benefit of the teachingsherein. No limitations are intended to the details of construction ordesign herein shown, other than as described in the claims below. It istherefore evident that the particular embodiments disclosed above can bealtered or modified and all such variations are considered within thescope of the disclosed subject matter. Accordingly, the protectionsought herein is as set forth in the claims below.

What is claimed is:
 1. A display system, configured to: set anillumination configuration to be applied during a frame period for eachframe of a sequence of frames based on a frame rate, the illuminationconfiguration, when applied, controlling: at least one of a firstillumination level and a duration for an illumination strobe; and atleast one of a second illumination level for a first illumination fillpreceding the illumination strobe in the frame period and a thirdillumination level for a second illumination fill following theillumination strobe in the frame period.
 2. The display system of claim1, wherein the display system is further configured to set theillumination configuration by: determining at least one of the firstillumination level or the duration of the illumination strobe based on afirst relationship with a frame rate range; and determining the secondillumination level of the first illumination fill preceding theillumination strobe based on a second relationship with the frame raterange; and determining the third illumination level of the secondillumination fill following the illumination strobe based on a thirdrelationship with the frame rate range.
 3. The display system of claim2, wherein: the first, second, and third relationships are implementedas one or more look-up tables.
 4. The display system of claim 2,wherein: the first, second, and third relationships are implemented asone or more functions of a software program executed at the displaysystem.
 5. The display system of claim 2, wherein: the first, second,and third relationships are implemented as one or more learned modelsgenerated by a machine learning algorithm executed at the displaysystem.
 6. The display system of claim 2, further comprising: a storagecomponent storing a software program to provide a graphical userinterface to receive user input to adjust at least one of the first,second, and third relationships.
 7. The display system of claim 2,wherein: the first relationship represents an increase in at least oneof the first illumination level and the duration of the illuminationstrobe as frame rate increases for at least a subset of the frame raterange; the second relationship represents a decrease in the secondillumination level of the first illumination fill preceding theillumination strobe at a first rate as frame rate increases for at leastthe subset of the frame rate range; and the third relationshiprepresents a decrease in the third illumination level of the secondillumination fill following the illumination strobe at a second rate asframe rate increases for at least the subset of the frame rate range. 8.The display system of claim 7, wherein the second rate is lower than thefirst rate.
 9. The display system of claim 7, wherein the second rate isequal to the first rate.
 10. The display system of claim 2, furthercomprising: a control module configured to set the illuminationconfiguration; and a display device configured to: receive arepresentation of the illumination configuration; and apply theillumination configuration during a frame period for each frame of thesequence of frames.
 11. The display system of claim 10, wherein: thedisplay device is a transmissive-type display device; and applying theillumination configuration during the frame period comprises controllinga backlight illumination level during the frame period based on theillumination configuration.
 12. The display system of claim 11, wherein:the display device is an emissive-type display device; and applying theillumination configuration during the frame period comprises adjustingpower supplied to pixels of the display device during the frame periodbased on the illumination configuration.
 13. A device, configured to:set an illumination configuration to be applied during a frame periodfor each frame of a sequence of frames to be displayed, the illuminationconfiguration being set based on a frame rate associated with thesequence of frames, and the illumination configuration, when applied,controlling at least one of: a first illumination level for anillumination strobe; a duration for the illumination strobe; a secondillumination level for a first illumination fill preceding theillumination strobe in the frame period; and a third illumination levelfor a second illumination fill following the illumination strobe in theframe period.
 14. The device of claim 13, wherein the device is furtherconfigured to set the illumination configuration by: determining atleast one of the first illumination level or the duration of theillumination strobe based on a first relationship with a frame raterange; and determining the second illumination level of the firstillumination fill preceding the illumination strobe based on a secondrelationship with the frame rate range; and determining the thirdillumination level of the second illumination fill following theillumination strobe based on a third relationship with the frame raterange.
 15. The device of claim 14, wherein: the first relationshiprepresents an increase in at least one of the first illumination leveland the duration of the illumination strobe as frame rate increases forat least a subset of the frame rate range; the second relationshiprepresents a decrease in the second illumination level of the firstillumination fill preceding the illumination strobe at a first rate asframe rate increases for at least the subset of the frame rate range;and the third relationship represents a decrease in the thirdillumination level of the second illumination fill following theillumination strobe at a second rate as frame rate increases for atleast the subset of the frame rate range.
 16. The device of claim 14,wherein: the first, second, and third relationships are implemented asone or more learned models generated by a machine learning algorithm.17. A display device, configured to: receive a representation of anillumination configuration; and apply the illumination configurationduring a frame period for each frame of a sequence of frames, whereinthe illumination configuration is associated with a frame rate at whichthe sequence of frames is to be displayed, and the illuminationconfiguration, when applied, controls at least one of: a firstillumination level for an illumination strobe; a duration for theillumination strobe; a second illumination level for a firstillumination fill preceding the illumination strobe in the frame period;and a third illumination level for a second illumination fill followingthe illumination strobe in the frame period.
 18. The display device ofclaim 17, wherein: at least one of the first illumination level or theduration of the illumination strobe are based on a first relationshipwith a frame rate range; the second illumination level of the firstillumination fill preceding the illumination strobe is based on a secondrelationship with the frame rate range; and the third illumination levelof the second illumination fill following the illumination strobe isbased on a third relationship with the frame rate range.
 19. The displaydevice of claim 17, wherein: the display device is a transmissive-typedisplay device; and applying the illumination configuration during theframe period comprises controlling a backlight illumination level duringthe frame period based on the illumination configuration.
 20. Thedisplay device of claim 17, wherein: the display device is anemissive-type display device; and applying the illuminationconfiguration during the frame period comprises adjusting power suppliedto pixels of the display device during the frame period based on theillumination configuration.